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publications [2019/09/02 07:51]
wigner_user [Reviews]
publications [2020/03/07 12:00]
weinbub [Condensed Matter: Optical and Transport properties of Systems]
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-======= ​Recent Publications and Publication History =======+======= Publication History =======
  
-====== ​Recent Publications ​====== +====== ​General / Inter-Disciplinary ​======
- +
-===== Books =====+
  
 +===== Books and Conference Proceedings =====
 +=== 2019 ===
 +  * [[Xavier Oriols]] and Jordi Mompart, [[http://​www.panstanford.com/​books/​9789814800105.html|Applied Bohmian Mechanics - From Nanoscale Systems to Cosmology, 2nd Edition]], (Pan Stanford Publishing, 2019)
 +  * Dagmar Bruss and [[Gerd Leuchs]], [[https://​www.wiley.com/​en-us/​Quantum+Information%3A+From+Foundations+to+Quantum+Technology+Applications%2C+2+Volume+Set%2C+2nd+Edition-p-9783527805792|Quantum Information:​ From Foundations to Quantum Technology Applications]],​ (Wiley, 2019)
 +  * [[David K. Ferry]], Stephen Goodnick, and [[Josef Weinbub]], [[http://​www.iue.tuwien.ac.at/​iwcn2019/​wp-content/​uploads/​2019/​06/​IW2-2019-Book-of-Abstracts.pdf|Book of Abstracts of the 3rd International Wigner Workshop (IW2)]] (TU Wien, 2019)
 +=== 2018 ===
   * [[David K. Ferry]] and [[Mihail (Mixi) Nedjalkov]],​ [[http://​iopscience.iop.org/​book/​978-0-7503-1671-2|The Wigner Function in Science and Technology]] (IOP Publishing, 2018)   * [[David K. Ferry]] and [[Mihail (Mixi) Nedjalkov]],​ [[http://​iopscience.iop.org/​book/​978-0-7503-1671-2|The Wigner Function in Science and Technology]] (IOP Publishing, 2018)
 +=== 2017 ===
 +  * [[Apostol Vourdas]], [[https://​www.springer.com/​gp/​book/​9783319594941|Finite and Profinite Quantum Systems]] (Springer, 2017)
 +  * [[Maurice de Gosson]], [[http://​www.worldscientific.com/​worldscibooks/​10.1142/​q0089|The Wigner Transform]],​ Advanced Textbooks in Mathematics (World Scientific, 2017)
 +  * [[Josef Weinbub]], [[David K. Ferry]], [[Irena Knezevic]], [[Mihail (Mixi) Nedjalkov]],​ and [[Siegfried Selberherr]],​ [[http://​www.iue.tuwien.ac.at/​pdf/​ib_2017/​hashed_links/​p54PChrcQOaqwqrCY_us.pdf|Book of Abstracts of the 2nd International Wigner Workshop (IW2)]] (TU Wien, 2017)
 +=== 2016 ===
 +  * [[Olafur Jonasson]], [[https://​homepages.cae.wisc.edu/​~knezevic/​pdfs/​Olafur_Jonasson_Dissertation_2016.pdf|Quantum Transport in Semiconductor Heterostructures Using Density-Matrix and Wigner-Function Formalisms]],​ PhD thesis, University of Wisconsin-Madison (2016)
 +  * [[Paul Ellinghaus]],​ [[http://​www.iue.tuwien.ac.at/​phd/​ellinghaus/​|Two-Dimensional Wigner Monte Carlo Simulation for Time-Resolved Quantum Transport with Scattering]],​ Doctoral dissertation,​ TU Wien (2016)
  
- +=== 2015 === 
-===== Journal Articles ===== +  * [[David K. Ferry]] ​and [[Josef Weinbub]], [[http://www.iue.tuwien.ac.at/pdf/ib_2015/hashed_links/p54PCkrcQOaqwqr9Y_us.pdf|Booklet of the 1st International Wigner Workshop ​(IW2)]] (TU Wien2015
-==== Reviews ==== +=== 2014 ===
-=== 2019 ===  +
-  * [[Giovanni Manfredi]], Paul-Antoine Hervieux and Jérôme Hurst, [[https://​arxiv.org/​abs/​1906.08165|Phase-space modelling of solid-state plasmas ]],  arXiv:​1906.08165 +
-=== 2018 ===  +
-  * [[Josef Weinbub]] and [[David K. Ferry]][[https://​aip.scitation.org/​doi/​10.1063/​1.5046663|Recent Advances in Wigner Function Approaches]], Appl. Phys. Rev. **5**, 041104 (2018) +
- +
-==== Regular Articles ==== +
-  * Chao Song, Kai Xu, Hekang Li, et al, "​Generation of multicomponent atomic Schrödinger cat states of up to 20 qubits" ​ [[https://​science.sciencemag.org/​content/​365/​6453/​574| Science 365, 574–577]] [[https://​arxiv.org/​abs/​1905.00320|arXiv]] 2019. +
-  * R.P. Rundle, [[Todd Tilma]], [[John Samson]], V.M. Dwyer, [[Raymond Bishop]] and [[Mark Everitt]]: "​General approach to quantum mechanics as a statistical theory"​ Phys Rev A. [[http://dx.doi.org/10.1103/​PhysRevA.99.012115|10.1103/PhysRevA.99.012115]] [[https://arxiv.org/abs/1708.03814|arXiv]] 2019. +
-  * [[Mihail ​(MixiNedjalkov]], [[Josef Weinbub]], M. Ballicchia, [[Siegfried Selberherr]],​ [[Ivan Dimov]], and [[David K. Ferry]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.99.014423|Wigner equation for general electromagnetic fields: The Weyl-Stratonovich transform]],​ Phys. Rev. B **99**, ​ 014423 ​(2019) +
-  * Yunfeng Xiong and [[Sihong Shao]][[http://​www.global-sci.com/​intro/​article_detail/​cicp/​12832.html|The Wigner Branching Random Walk: Efficient Implementation and Performance Evaluation]],​ Commun. Comput. Phys **25**, 871 (2019) +
--------------------------- +
-====== ​Publication History ====== +
- +
-===== Books ===== +
- +
-  * [[David K. Ferry]] and [[Mihail (Mixi) Nedjalkov]],​ [[http://​iopscience.iop.org/​book/​978-0-7503-1671-2|The Wigner Function in Science and Technology]] (IOP Publishing, 2018)+
   * T. L. Curtright, D. B. Fairlie and C. K. Zachos, [[https://​www.worldscientific.com/​worldscibooks/​10.1142/​8870|A Concise Treatise on Quantum Mechanics in Phase Space]] (World Scientific Publishing Co Pte Ltd, 2014)   * T. L. Curtright, D. B. Fairlie and C. K. Zachos, [[https://​www.worldscientific.com/​worldscibooks/​10.1142/​8870|A Concise Treatise on Quantum Mechanics in Phase Space]] (World Scientific Publishing Co Pte Ltd, 2014)
-  ​* D. Querlioz and P. Dollfus, [[https://​onlinelibrary.wiley.com/​doi/​book/​10.1002/​9781118618479|The Wigner Monte Carlo Method for Nanoelectronic Devices]] (John Wiley & Sons, Inc. 2010)+=== 2013 === 
 +  * [[Damien Querlioz]] and [[Philippe Dollfus]], [[https://​onlinelibrary.wiley.com/​doi/​book/​10.1002/​9781118618479|The Wigner Monte-Carlo Method for Nanoelectronic Devices: A Particle Description of Quantum Transport and Decoherence]] (John Wiley & Sons, 2013) 
 +=== 2012 === 
 +  * [[Xavier Oriols]] and Jordi Mompart, [[http://​www.panstanford.com/​books/​9789814316392.html|Applied Bohmian Mechanics - From Nanoscale Systems to Cosmology]],​ (Pan Stanford Publishing, 2012) 
 +=== 2010 === 
 +  ​* D. Querlioz and P. Dollfus, [[https://​onlinelibrary.wiley.com/​doi/​book/​10.1002/​9781118618479|The Wigner Monte Carlo Method for Nanoelectronic Devices]] (John Wiley & Sons, 2010) 
 +=== 2005 ===
   * C. K. Zachos, D. B. Fairlie and T. L. Curtright, [[https://​doi.org/​10.1142/​5287|Quantum Mechanics in Phase Space. An Overview with Selected Papers]] (World Scientific Publishing Co Pte Ltd, 2005)   * C. K. Zachos, D. B. Fairlie and T. L. Curtright, [[https://​doi.org/​10.1142/​5287|Quantum Mechanics in Phase Space. An Overview with Selected Papers]] (World Scientific Publishing Co Pte Ltd, 2005)
-  ​WP. Schleich, [[https://​onlinelibrary.wiley.com/​doi/​book/​10.1002/​3527602976|Quantum Optics in Phase Space]] (Wiley‐VCH Verlag Berlin GmbH, 2001)+=== 2003 === 
 +  ​[[Christoph Jungemann]] and Bernd Meinerzhagen,​ [[https://​www.springer.com/​gp/​book/​9783211013618|Hierarchical Device Simulation]],​ (Springer, 2003) 
 +=== 2001 === 
 +  * [[Wolfgang ​Schleich]], [[https://​onlinelibrary.wiley.com/​doi/​book/​10.1002/​3527602976|Quantum Optics in Phase Space]] (Wiley‐VCH Verlag Berlin GmbH, 2001) 
 +=== 1998 === 
 +  * [[Hans Georg Feichtinger]] and Thomas Strohmer, [[https://​www.springer.com/​gp/​book/​9780817639594|Gabor Analysis and Algorithms]],​ (Springer, 1998) 
 +=== 1991 ===
   * Y. S. Kim and M. E. Noz, [[https://​doi.org/​10.1142/​1197|Phase Space Picture of Quantum Mechanics. Group Theoretical Approach]] (World Scientific, 1991)   * Y. S. Kim and M. E. Noz, [[https://​doi.org/​10.1142/​1197|Phase Space Picture of Quantum Mechanics. Group Theoretical Approach]] (World Scientific, 1991)
-  ​* S. R. Groot, [[La transformation de Weyl et la fonction de Wigner, une forme alternative de la +=== 1974 === 
 +  ​* S. R. Groot, [[https://​cheap-library.com/​book/​23c997f932b9bc0e28708bdd792fda0a|La transformation de Weyl et la fonction de Wigner, une forme alternative de la 
 mecanique quantique]] (Les Presses de l'​Universitié de Montréal, 1974) mecanique quantique]] (Les Presses de l'​Universitié de Montréal, 1974)
  
 ===== Journal Articles ===== ===== Journal Articles =====
- 
-==== Genesis ====  
-  * J. E. Moyal, [[https://​doi.org/​10.1017/​S0305004100000487|Quantum mechanics as a statistical theory]] Proc. Cambridge Phil. Soc. **45**, 99 (1949) 
-  * H. J. Groenewold, [[https://​doi.org/​10.1016/​S0031-8914(46)80059-4|On the principles of elementary quantum mechanics]] Physica **12**, 405 (1946) 
-   * E. P. Wigner, [[https://​link.aps.org/​doi/​10.1103/​PhysRev.40.749|On the Quantum Correction For Thermodynamic Equilibrium]],​ Phys. Rev. **40**, 749 (1932) 
  
 ==== Reviews ==== ==== Reviews ====
  
 +=== 2018 ===
   * [[Josef Weinbub]] and [[David K. Ferry]], [[https://​aip.scitation.org/​doi/​10.1063/​1.5046663|Recent Advances in Wigner Function Approaches]],​ Appl. Phys. Rev. **5**, 041104 (2018)   * [[Josef Weinbub]] and [[David K. Ferry]], [[https://​aip.scitation.org/​doi/​10.1063/​1.5046663|Recent Advances in Wigner Function Approaches]],​ Appl. Phys. Rev. **5**, 041104 (2018)
 +=== 2016 ===
   * Y. P. Kalmykov, ​ W. T. Coffey and S. V. Titov, [[ https://​doi.org/​10.1002/​9781119290971.ch2|Spin relaxation in phase space]], Adv. Chem. Phys.**161**,​ 41 (2016)   * Y. P. Kalmykov, ​ W. T. Coffey and S. V. Titov, [[ https://​doi.org/​10.1002/​9781119290971.ch2|Spin relaxation in phase space]], Adv. Chem. Phys.**161**,​ 41 (2016)
 +=== 2015 ===
 +  * [[Jonathan Petruccelli]] and [[Miguel A. Alonso]], [[https://​onlinelibrary.wiley.com/​doi/​abs/​10.1002/​9783527600441.oe1013|The Wigner function in optics]], in: The Optics Encyclopedia (Wiley VCH, 2015)
 +=== 2011 ===
 +  * [[Miguel A. Alonso]], [[https://​www.osapublishing.org/​aop/​abstract.cfm?​uri=aop-3-4-272|Wigner functions in optics: describing beams as ray bundles and pulses as particle ensembles]],​ Adv. Opt. Photon. **3**, 272 (2011)
 +=== 1995 ===
   * H.-W. Lee, [[https://​doi.org/​10.1016/​0370-1573(95)00007-4|Theory and application of the quantum phase-space distribution functions]],​ Phys. Rep. **259**, ​ 147 (1995)   * H.-W. Lee, [[https://​doi.org/​10.1016/​0370-1573(95)00007-4|Theory and application of the quantum phase-space distribution functions]],​ Phys. Rep. **259**, ​ 147 (1995)
 +=== 1986 ===
   * K. Takahashi, [[https://​doi.org/​10.1143/​JPSJ.55.762|Wigner and Husimi Functions in Quantum Mechanics]],​ J. Phys. Soc. Jpn. **55**, ​ 762 (1986)   * K. Takahashi, [[https://​doi.org/​10.1143/​JPSJ.55.762|Wigner and Husimi Functions in Quantum Mechanics]],​ J. Phys. Soc. Jpn. **55**, ​ 762 (1986)
 +=== 1984 ===
   * M. Hillery, ​ R. F. O'​Connell, ​ M.O. Scully, ​ and E. P. Wigner, [[https://​doi.org/​10.1016/​0370-1573(84)90160-1|Distribution functions in physics: Fundamentals]],​ Phys. Rep. **106**, 121 (1984)   * M. Hillery, ​ R. F. O'​Connell, ​ M.O. Scully, ​ and E. P. Wigner, [[https://​doi.org/​10.1016/​0370-1573(84)90160-1|Distribution functions in physics: Fundamentals]],​ Phys. Rep. **106**, 121 (1984)
 +=== 1983 ===
   * V. I. Tatarskiĭ,​[[https://​doi.org/​10.1070/​PU1983v026n04ABEH004345|The Wigner representation of quantum mechanics]],​ Sov. Phys. Usp. **26**, 311 (1983)   * V. I. Tatarskiĭ,​[[https://​doi.org/​10.1070/​PU1983v026n04ABEH004345|The Wigner representation of quantum mechanics]],​ Sov. Phys. Usp. **26**, 311 (1983)
   * P. Carruthers and F. Zachariasen,​ [[https://​link.aps.org/​doi/​10.1103/​RevModPhys.55.245|Quantum collision theory with phase-space distributions]],​ Rev. Mod. Phys. **55**, ​ 245 (1983)   * P. Carruthers and F. Zachariasen,​ [[https://​link.aps.org/​doi/​10.1103/​RevModPhys.55.245|Quantum collision theory with phase-space distributions]],​ Rev. Mod. Phys. **55**, ​ 245 (1983)
 +=== 1958 ===
   * G. A. Baker, Jr., [[https://​doi.org/​10.1103/​PhysRev.109.2198|Formulation of Quantum Mechanics Based on the Quasi-Probability Distribution Induced on Phase Space]], Phys. Rev. **109**, 2198 (1958)   * G. A. Baker, Jr., [[https://​doi.org/​10.1103/​PhysRev.109.2198|Formulation of Quantum Mechanics Based on the Quasi-Probability Distribution Induced on Phase Space]], Phys. Rev. **109**, 2198 (1958)
  
  
 +==== Genesis ==== 
 +=== 1949 ===
 +  * J. E. Moyal, [[https://​doi.org/​10.1017/​S0305004100000487|Quantum mechanics as a statistical theory]] Proc. Cambridge Phil. Soc. **45**, 99 (1949)
 +=== 1946 ===
 +  * H. J. Groenewold, [[https://​doi.org/​10.1016/​S0031-8914(46)80059-4|On the principles of elementary quantum mechanics]] Physica **12**, 405 (1946)
 +=== 1932 ===
 +   * E. P. Wigner, [[https://​link.aps.org/​doi/​10.1103/​PhysRev.40.749|On the Quantum Correction For Thermodynamic Equilibrium]],​ Phys. Rev. **40**, 749 (1932)
  
 +
 +
 +====== Topics ======
  
 ==== Classical, Semiclassical and Quantum Physics ====  ==== Classical, Semiclassical and Quantum Physics ==== 
 === 2019 ===  === 2019 === 
-  * Chao SongKai XuHekang Liet al"​Generation ​of multicomponent atomic Schrödinger ​cat states ​of up to 20 qubits" ​ ​[[https://​science.sciencemag.org/content/365/6453/574Science 365574–577]] [[https://arxiv.org/abs/1905.00320|arXiv]] 2019+  * T. Ikeda and [[Yoshitaka Tanimura]][[https://​pubs.acs.org/​doi/​abs/​10.1021/​acs.jctc.8b01195|Low-Temperature Quantum Fokker–Planck and Smoluchowski Equations and Their Extension to Multistate Systems]]J. Chem. Theory Comput. **15**2517-2534 (2019) 
-  * R.PRundle, [[Todd Tilma]], [[John Samson]], V.MDwyer, [[Raymond Bishop]] and [[Mark Everitt]]: "​General approach ​to quantum ​mechanics as a statistical theory" ​Phys Rev A. [[http://dx.doi.org/​10.1103/​PhysRevA.99.012115|10.1103/PhysRevA.99.012115]] [[https://arxiv.org/abs/1708.03814|arXiv]] 2019. +  * Maxime Oliva and [[Ole Steuernagel]][[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.99.032104|Quantum Kerr oscillators'​ evolution in phase space: Wigner current, symmetries, shear suppression,​ and special states]], Phys. Rev. A **99**, 032104 (2019) 
-  * [[Mihail ​(MixiNedjalkov]], [[Josef Weinbub]], M. Ballicchia, [[Siegfried Selberherr]], [[Ivan Dimov]], and [[David KFerry]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.99.014423|Wigner equation for general electromagnetic fields: The Weyl-Stratonovich transform]], Phys. Rev. **99**,  ​014423 ​(2019)+  * Maxime Oliva and [[Ole Steuernagel]],​ [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.122.020401|Dynamic Shear Suppression in Quantum Phase Space]], Phys. Rev. Lett. **122**, 020401 (2019) 
 +  * Z. Xiao, T. Fuse, S. Ashhab, F. Yoshihara, [[Kouichi Semba]], M. Sasaki, M. Takeoka, and J. P. Dowling, [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.99.013827|Fast amplification and rephasing ​of entangled ​cat states ​in a qubit-oscillator system]], Phys. Rev. A **99**, 013827 (2019) 
 +  * T. Hahn, D. Groll, T. Kuhn and [[Daniel Wigger]], ​[[https://journals.aps.org/prb/abstract/10.1103/PhysRevB.100.024306|Influence of excited state decay and dephasing on phonon quantum state preparation]]Phys. Rev. B **100**, 024306 (2019) 
 +  * [[Guillem Albareda Piquer]], Aaron Kelly, and Angel Rubio, ​[[https://journals.aps.org/prmaterials/abstract/​10.1103/​PhysRevMaterials.3.023803|Nonadiabatic quantum dynamics without potential energy surfaces]], PhysRev. Materials **3**, 023803 (2019) 
 +  * Eric GArrais, Diego AWisniackiAugusto J. Roncaglia, and [[Fabricio Toscano]], [[https://​journals.aps.org/​pre/​abstract/​10.1103/​PhysRevE.100.052136|Work statistics for sudden quenches in interacting quantum many-body systems]], PhysRevE **100**052136 (2019) 
 +  * A. Frisk Kockum, A. Miranowicz, S. De Liberato, S. Savasta, and [[Franco Nori]], [[https://​www.nature.com/​articles/​s42254-018-0006-2|Ultrastrong coupling between light and matter]], Nature Rev. Phys. **1**, 19 (2019) 
 +  * W. Qin, A. Miranowicz, G. Long, J.Q. You, and [[Franco Nori]], [[https://​www.nature.com/​articles/​s41534-019-0172-9|Proposal ​to test quantum ​wave-particle superposition on massive mechanical resonators]],​ npj Quant. Inf. **5**, 58 (2019) 
 +  * Hong-Bin Chen, Ping-Yuan Lo, Clemens Gneiting, Joonwoo Bae, Yueh-Nan Chen, and [[Franco Nori]], [[https://​www.nature.com/​articles/​s41467-019-11502-4|Quantifying the nonclassicality of pure dephasing]],​ Nature Comm. **10**, 3794 (2019) 
 +  * Gui-Lei Zhu, Xin-You Lü, Li-Li Zheng, Zhi-Ming Zhan, [[Franco Nori]], and Ying Wu, [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.100.023825|Single-photon-triggered quantum chaos]], ​PhysRev**100**, 023825 (2019) 
 +  * JTuorila, J. Stockburger,​ T. Ala-Nissila, ​[[Joachim Ankerhold]],​ and Mikko Möttönen, [[https://journals.aps.org/​prresearch/​abstract/10.1103/PhysRevResearch.1.013004|System-environment correlations in qubit initialization and control]], Phys. Rev. Res. **1**, 013004 (2019) 
 +  * J. Gosner, B. Kubala, and [[Joachim Ankerhold]],​ [[https://​journals.aps.org/​prb/​abstract/​10.1103/PhysRevB.99.144524|Quantum properties of a strongly driven Josephson junction]], Phys. Rev. B **99**, 144524 (2019) 
 +  * S. Dambach, [[Andrew Armour]], B. Kubala, and [[Joachim Ankerhold]], ​[[https://iopscience.iop.org/article/10.1088/​1402-4896/​ab2a90/​meta|Josephson junction cavity systems as cousins of the quantum optical micromaser]], Phys. Script. **94**, 104001 (2019
 +  * SDambacha, P. Egetmeyer, [[Joachim Ankerhold]],​ and B. Kubala, [[https://​link.springer.com/​article/​10.1140%2Fepjst%2Fe2018-800062-8|Quantum thermodynamics with a Josephson-photonics setup]], Europ. Phys. J. Spec. Top. **227**, 2053 (2019) 
 +  * Chao Song, Kai Xu, Hekang Li, et al., [[https://​science.sciencemag.org/​content/​365/​6453/​574|Generation of multicomponent atomic Schrödinger cat states of up to 20 qubits]], Science **365**, 574 (2019) 
 +  * R.P. Rundle, [[Todd Tilma]], [[John Samson]], V.M. Dwyer, [[Raymond Bishop]], and [[Mark Everitt]], [[http://dx.doi.org/​10.1103/​PhysRevA.99.012115|General approach to quantum mechanics as a statistical theory]], Phys Rev A **99**, 012115 (2019) 
 +  * B.I. Davies, R.P. Rundle, V.M. Dwyer, [[John Samson]], [[Todd Tilma]], and [[Mark Everitt]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.100.042102|Visualizing spin degrees of freedom in atoms and molecules]], Phys. Rev. **100**, 042102 (2019) 
 +  * Tian Zhang, [[Oscar C O Dahlsten]], and Vlatko Vedral, [[https://​arxiv.org/​abs/​1903.06312|Constructing continuous-variable spacetime quantum states from measurement correlations]],​ arXiv (2019) 
 === 2018 === === 2018 ===
 +  * Jack Clarke and [[Michael R. Vanner]], [[https://​iopscience.iop.org/​article/​10.1088/​2058-9565/​aada1d/​meta|Growing macroscopic superposition states via cavity quantum optomechanics]],​ Quantum Science and Technology **4**, 014003 (2018)
 +  * K. E. Khosla, [[Michael R. Vanner]], N. Ares, and E. A. Laird, [[https://​journals.aps.org/​prx/​abstract/​10.1103/​PhysRevX.8.021052|Displacemon Electromechanics:​ How to Detect Quantum Interference in a Nanomechanical Resonator]],​ Phys. Rev. X **8**, 021052 (2018)
 +  * T. Ikeda and [[Yoshitaka Tanimura]], [[https://​doi.org/​10.1016/​j.chemphys.2018.07.013|Phase-Space Wavepacket Dynamics of Internal Conversion via Conical Intersection:​ Multi-State Quantum Fokker-Planck Equation Approach]], Chem. Phys. **515**, 203-213 (2018)
 +  * V. M. Bastidas, B. Renoust, [[Kae Nemoto]], and W. J. Munro, [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.98.224307|Ergodic-localized junctions in periodically driven systems]], Phys. Rev. B **98**, 224307 (2018)
 +  * [[Omar Morandi]], [[https://​iopscience.iop.org/​article/​10.1088/​1751-8121/​aac3ef/​meta|Quantum motion with trajectories:​ beyond the Gaussian beam approximation]],​ J. Phys. A: Math. Theor. **51**, 255301 (2018)
 +  * Demid V. Sychev, Alexander E. Ulanov, Egor S. Tiunov, Anastasia A. Pushkina, A. Kuzhamuratov,​ Valery Novikov, and [[Alexander Lvovsky]], [[https://​www.nature.com/​articles/​s41467-018-06055-x|Entanglement and teleportation between polarization and wave-like encodings of an optical qubit]], Nature Comm. **9**, 3672 (2018)
 +  *  L. Happ, [[Maxim A. Efremov]], H. Nha, and [[Wolfgang Schleich]], [[https://​iopscience.iop.org/​article/​10.1088/​1367-2630/​aaac25|Sufficient condition for a quantum state to be genuinely quantum non-Gaussian]],​ New J. Phys. **20**, 039601 (2018)
 +  * Manuel R. Gonçalves, [[William B. Case]], Ady Arie, and [[Wolfgang Schleich]], [[https://​link.springer.com/​chapter/​10.1007/​978-3-319-64346-5_30|Single-Slit Focusing and Its Representations]],​ Expl. Worl. Las., 529 (2018)
 +  * R.P. Rundle, B.I. Davies, V.M. Dwyer, [[Todd Tilma]], and [[Mark Everitt]], [[https://​arxiv.org/​abs/​1809.10564|Quantum State Spectroscopy of Atom-Cavity Systems]], arXiv (2018)
 +  * M. Filipovic and [[Wolfgang Belzig]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.97.115441|Shot noise of charge and spin transport in a junction with a precessing molecular spin]], Phys. Reg. B **97**, 115441 (2018)
 +  * Johannes Bulte, Adam Bednorz, [[Christoph Bruder]], and [[Wolfgang Belzig]], [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.120.140407|Noninvasive Quantum Measurement of Arbitrary Operator Order by Engineered Non-Markovian Detectors]],​ Phys. Rev. Lett **120**, 140407 (2018)
   * R. Sala Mayato, P. Loughlin, and [[Leon Cohen]], [[https://​doi.org/​10.1016/​j.physleta.2018.08.012|M-indeterminate distributions in quantum mechanics and the non-overlapping wave function paradox]], Phys. Lett. A **382**, ​ 2914 (2018)   * R. Sala Mayato, P. Loughlin, and [[Leon Cohen]], [[https://​doi.org/​10.1016/​j.physleta.2018.08.012|M-indeterminate distributions in quantum mechanics and the non-overlapping wave function paradox]], Phys. Lett. A **382**, ​ 2914 (2018)
   * V. Filinov, A. Larkin, [[https://​doi.org/​10.3390/​universe4120133|Quantum Dynamics of Charged Fermions ​   * V. Filinov, A. Larkin, [[https://​doi.org/​10.3390/​universe4120133|Quantum Dynamics of Charged Fermions ​
Line 67: Line 119:
   * Mauricio Reis and Adelcio C. Oliveira, [[https://​ieeexplore.ieee.org/​document/​8610886|Roughness as Entanglement Witness: The two Coupled Cavity Model]], SBFoton IOPC **2018**, 1 (2018)   * Mauricio Reis and Adelcio C. Oliveira, [[https://​ieeexplore.ieee.org/​document/​8610886|Roughness as Entanglement Witness: The two Coupled Cavity Model]], SBFoton IOPC **2018**, 1 (2018)
   * Alex E. Bernardini, [[https://​link.aps.org/​doi/​10.1103/​PhysRevA.98.052128|Testing nonclassicality with exact Wigner currents for an anharmonic quantum system]], Phys. Rev. A **98**, 052128 (2018)   * Alex E. Bernardini, [[https://​link.aps.org/​doi/​10.1103/​PhysRevA.98.052128|Testing nonclassicality with exact Wigner currents for an anharmonic quantum system]], Phys. Rev. A **98**, 052128 (2018)
 +
 +
 === 2017 === === 2017 ===
 +  * T. Ikeda and [[Yoshitaka Tanimura]], [[https://​doi.org/​10.1063/​1.4989537|Probing photoisomerization processes by means of multi-dimensional electronic spectroscopy:​ The multi-state quantum hierarchal Fokker-Planck Equation approach]], J. Chem. Phys. **146**, 014102 (2017)
 +  * X. Gu, A.F. Kockum, A. Miranowicz, Y.X. Liu, and [[Franco Nori]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0370157317303290|Microwave photonics with superconducting quantum circuits]], Phys. Rep. **718-719**,​ 1 (2017)
 +  * J. Zhang, Y.X. Liu, R.B. Wu, K. Jacobs, and [[Franco Nori]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0370157317300479|Quantum feedback: theory, experiments,​ and applications]],​ Phys. Rep. **679**, 1 (2017)
 +  * [[Andrew Armour]], B. Kubala, and [[Joachim Ankerhold]],​ [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.96.214509|Noise switching at a dynamical critical point in a cavity-conductor hybrid]], Phys. Rev. B **96**, 214509 (2017)
   * R.P. Rundle, P.W. Mills, [[Todd Tilma]], [[John Samson]], [[Mark Everitt]]: “Simple procedure for phase-space measurement and entanglement validation”, ​ Phys Rev A.[[http://​dx.doi.org/​10.1103/​PhysRevA.96.022117|10.1103/​PhysRevA.96.022117]] [[https://​arxiv.org/​abs/​1605.08922|arXiv]],​ 2017.   * R.P. Rundle, P.W. Mills, [[Todd Tilma]], [[John Samson]], [[Mark Everitt]]: “Simple procedure for phase-space measurement and entanglement validation”, ​ Phys Rev A.[[http://​dx.doi.org/​10.1103/​PhysRevA.96.022117|10.1103/​PhysRevA.96.022117]] [[https://​arxiv.org/​abs/​1605.08922|arXiv]],​ 2017.
   * Alex E. Bernardini and Mariana Chinaglia, [[https://​doi.org/​10.1088/​1742-6596/​880/​1/​012038|Topological view of quantum tunneling coherent destruction]],​ J. Phys.: Conf. Ser.  **880**, 012038 (2017)   * Alex E. Bernardini and Mariana Chinaglia, [[https://​doi.org/​10.1088/​1742-6596/​880/​1/​012038|Topological view of quantum tunneling coherent destruction]],​ J. Phys.: Conf. Ser.  **880**, 012038 (2017)
   * Alex E. Bernardini and Orfeu Bertolami, [[https://​doi.org/​10.1209/​0295-5075/​120/​20002|Non-classicality from the phase-space flow analysis of the Weyl-Wigner quantum mechanics]],​ EPL **120**, 20002 (2017)   * Alex E. Bernardini and Orfeu Bertolami, [[https://​doi.org/​10.1209/​0295-5075/​120/​20002|Non-classicality from the phase-space flow analysis of the Weyl-Wigner quantum mechanics]],​ EPL **120**, 20002 (2017)
-  * A. Larkin, V. Filinov, [[https://​www.doi.org/​10.4236/​jamp.2017.52035|Phase Space Path Integral Representation for Wigner Function]], ​JAMP **5**, 392 (2017)+  * A. Larkin, V. Filinov, [[https://​www.doi.org/​10.4236/​jamp.2017.52035|Phase Space Path Integral Representation for Wigner Function]], ​Journal of Applied Mathematics and Physics ​**5**, 392 (2017) 
 +  * Dimitris Kakofengitis and [[Ole Steuernagel]],​ [[https://​link.springer.com/​article/​10.1140/​epjp/​i2017-11634-2|Wigner'​s quantum phase space current in weakly anharmonic weakly excited two-state systems]], European Physical Journal Plus. **132**, 381 (2017) 
 +  * Dimitris Kakofengitis,​ Maxime Oliva, and [[Ole Steuernagel]],​ [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.95.022127|Wigner'​s representation of quantum mechanics in integral form and its applications]],​ Physical Review A. **95**, 022127 (2017) 
 === 2016 === === 2016 ===
 +  * R. Grossmann, A. Sakurai, and [[Yoshitaka Tanimura]], [[https://​journals.jps.jp/​doi/​10.7566/​JPSJ.85.034803|Electron pumping under non-Markovian dissipation:​ The role of the self-consistent field]], J. Phys. Soc. Jpn. **85**, 034803 (2016) ​
 +  * [[Daniel Wigger]], H. Gehring, V.M. Axt, [[Doris Reiter]] and T. Kuhn, [[https://​link.springer.com/​article/​10.1007/​s10825-016-0856-8|Quantum dynamics of optical phonons generated by optical excitations of a quantum dot]], J. Comput. Electron **15**, 1158 (2016)
   * [[Todd Tilma]], [[Mark Everitt]], [[John Samson]], W. J. Munro, and [[Kae Nemoto]]: “Wigner Functions for Arbitrary Quantum Systems”, ​ Phys. Rev. Lett., Vol.117, 180401, DOI: [[http://​dx.doi.org/​10.1103/​PhysRevLett.117.180401|10.1103/​PhysRevLett.117.180401]],​ [[https://​arxiv.org/​abs/​1601.07772|arXiv]],​ 2016.   * [[Todd Tilma]], [[Mark Everitt]], [[John Samson]], W. J. Munro, and [[Kae Nemoto]]: “Wigner Functions for Arbitrary Quantum Systems”, ​ Phys. Rev. Lett., Vol.117, 180401, DOI: [[http://​dx.doi.org/​10.1103/​PhysRevLett.117.180401|10.1103/​PhysRevLett.117.180401]],​ [[https://​arxiv.org/​abs/​1601.07772|arXiv]],​ 2016.
   * A. S. Larkin, V. S. Filinov, and V. E. Fortov, [[https://​doi.org/​10.1002/​ctpp.201500078|Path Integral Representation of the Wigner Function in Canonical Ensemble]], Contrib. Plasma Phys. **56**, 187 (2016)   * A. S. Larkin, V. S. Filinov, and V. E. Fortov, [[https://​doi.org/​10.1002/​ctpp.201500078|Path Integral Representation of the Wigner Function in Canonical Ensemble]], Contrib. Plasma Phys. **56**, 187 (2016)
   * Jonas F. G. Santos and Alex E. Bernardini, [[https://​doi.org/​10.1016/​j.physa.2015.10.033|Gaussian fidelity distorted by external fields]], Phys. A **445**, 75 (2016)   * Jonas F. G. Santos and Alex E. Bernardini, [[https://​doi.org/​10.1016/​j.physa.2015.10.033|Gaussian fidelity distorted by external fields]], Phys. A **445**, 75 (2016)
 +  * Keyu Xia, Mattias Johnsson, [[Peter Knight]], and Jason Twamley, [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.116.023601|Cavity-Free Scheme for Nondestructive Detection of a Single Optical Photon]], Phys. Rev. Lett. **116**, 023601 (2016)
 +  * Yin Long Lin and [[Oscar C O Dahlsten]], [[https://​arxiv.org/​abs/​1607.01764|Tunnelling necessitates negative Wigner function]], arXiv (2016)
 +
 === 2015 === === 2015 ===
 +  * [[Yoshitaka Tanimura]], [[https://​aip.scitation.org/​doi/​10.1063/​1.4916647|Real-Time and Imaginary-Time Quantum Hierarchal Fokker-Planck Equations]],​ J. Chem. Phys. **142**, 144110 (2015)
 +  * Peter Degenfeld-Schonburg,​ Carlos Navarrete–Benlloch,​ and [[Michael J. Hartmann]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.91.053850|Self-consistent projection operator theory in nonlinear quantum optical systems: A case study on degenerate optical parametric oscillators]],​ Phys. Rev. A **91**, 053850 (2015)
 +  * Mehdi Abdi, Matthias Pernpeintner,​ Rudolf Gross, Hans Huebl, and [[Michael J. Hartmann]], [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.114.173602|Quantum State Engineering with Circuit Electromechanical Three-Body Interactions]],​ Phys. Rev. Lett. **114**, 173602 (2015)
   * Catarina Bastos, Alex E. Bernardini, and Jonas F. G. Santos, [[https://​doi.org/​10.1016/​j.physa.2015.07.009|Probing phase-space noncommutativity through quantum mechanics and thermodynamics of free particles and quantum rotors]], Phys. A **438**, 340 (2015) ​   * Catarina Bastos, Alex E. Bernardini, and Jonas F. G. Santos, [[https://​doi.org/​10.1016/​j.physa.2015.07.009|Probing phase-space noncommutativity through quantum mechanics and thermodynamics of free particles and quantum rotors]], Phys. A **438**, 340 (2015) ​
   * J. T. Mendonça, W. Horton, R. M. O. Galvão and Yves Elskens, [[https://​doi.org/​10.1017/​S0022377814001032|Transport equations for lower hybrid waves in a turbulent plasma]], J. Plasma Physics **81**, 905810206 (2015)   * J. T. Mendonça, W. Horton, R. M. O. Galvão and Yves Elskens, [[https://​doi.org/​10.1017/​S0022377814001032|Transport equations for lower hybrid waves in a turbulent plasma]], J. Plasma Physics **81**, 905810206 (2015)
   * O de los Santos-Sánchez,​ J Récamier and R Jáuregui, [[https://​doi.org/​10.1088/​0031-8949/​90/​7/​074018|Markovian master equation for nonlinear systems]], Phys. Scr. **90**, 074018 (2015)   * O de los Santos-Sánchez,​ J Récamier and R Jáuregui, [[https://​doi.org/​10.1088/​0031-8949/​90/​7/​074018|Markovian master equation for nonlinear systems]], Phys. Scr. **90**, 074018 (2015)
 +  * [[Andras Dombi]], [[Andras Vukics]], and [[Peter Domokos]], [[https://​link.springer.com/​article/​10.1140/​epjd/​e2015-50861-9|Bistability effect in the extreme strong coupling regime of the Jaynes-Cummings model]], Europ. Phys. J. D **69**, 60 (2015)
 +  * [[David K. Ferry]], [[http://​link.springer.com/​article/​10.1007%2Fs10825-015-0731-z|Phase-Space Functions: Can They Give a Different View of Quantum Mechanics?​]],​ J. Comp. Electron. **14**, 864 (2015)
 +  * [[David K. Ferry]], R. Akis, and R. Brunner, [[http://​iopscience.iop.org/​article/​10.1088/​0031-8949/​2015/​T165/​014010/​meta|Probing the Quantum - Classical Connection with Open Quantum Dots]], Phys. Script. **2015**, T165 (2015)
 +
 +
 +=== 2014 ===
 +  * A. Sakurai and [[Yoshitaka Tanimura]], [[http://​iopscience.iop.org/​article/​10.1088/​1367-2630/​16/​1/​015002/​meta|Self-excited current oscillations in a resonant tunneling diode described by a model based on the Caldeira-Leggett Hamiltonian]],​ New J. of Phys. **16**, 015002 (2014)
 +  * I. Georgescu, S. Ashhab, and [[Franco Nori]], [[https://​journals.aps.org/​rmp/​abstract/​10.1103/​RevModPhys.86.153|Quantum Simulation]],​ Rev. Mod. Phys. **86**, 153 (2014)
 +  * Miranowicz, J. Bajer, M. Paprzycka, Y.X. Liu, A.M. Zagoskin, and [[Franco Nori]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.90.033831|State-dependent photon blockade via quantum-reservoir engineering]],​ Phys. Rev. A **90**, 033831 (2014)
 +  * T. Jullien, P. Roulleau, B. Roche, A. Cavanna, Y. Jin, and [[Christian Glattli]], [[https://​www.nature.com/​articles/​nature13821|Quantum tomography of an electron]], Nature **514**, 603 (2014) ​
 +  * [[Mark Everitt]], Timothy P. Spiller, Gerard J. Milburn, Richard D. Wilson, and Alexandre M. Zagoskin, [[https://​www.frontiersin.org/​articles/​10.3389/​fict.2014.00001/​full|Engineering dissipative channels for realizing Schrödinger cats in SQUIDs]], Front. ICT **1**, 1 (2014)
 +  * T. L. Curtright, D. B. Fairlie and C. K. Zachos, [[https://​www.worldscientific.com/​worldscibooks/​10.1142/​8870|A Concise Treatise on Quantum Mechanics in Phase Space]] (World Scientific Publishing Co Pte Ltd, 2014)
 +  * [[Peter Adam]], V.A. Andreev, I. Ghiu, A. Isar, M.A. Man'ko and V.I. Man'​ko,​ [[http://​dx.doi.org/​10.1007/​s10946-014-9444-1|Finite Phase Space, Wigner Functions, and Tomography for Two-Qubit States]], ​ J. Russ. Las. Res. **35**, 427 (2014)
 +  * [[Peter Adam]], V.A. Andreev, I. Ghiu, A. Isar, M.A. Man'ko and V.I. Man'​ko,​ [[http://​dx.doi.org/​10.1007/​s10946-014-9395-6|Wigner Functions and Spin Tomograms for Qubit States]], J. Russ. Las. Res. **35**, 3 (2014)
 +  * [[Enno Giese]], Wolfgang Zeller, Stephan Kleinert, Matthias Meister, Vincenzo Tamma, [[Albert Roura]], and [[Wolfgang Schleich]], [[http://​ebooks.iospress.nl/​publication/​38097|The interface of gravity and quantum mechanics illuminated by Wigner phase space]], Proc. Intern. School Phys “Enrico Fermi” **188**, 171 (2014)
 +  * D. Bakalov and [[Stephan Schiller]], [[https://​link.springer.com/​article/​10.1007/​s00340-013-5703-z|The electric quadrupole moment of molecular hydrogen ions and their potential for a molecular ion clock]], Appl. Phys. B **114**, 213 (2014)
 +
 +=== 2013 ===
 +  * A. Kato and [[Yoshitaka Tanimura]], [[https://​pubs.acs.org.ccindex.cn/​doi/​abs/​10.1021/​jp403056h|Quantum Suppression of Ratchet Rectification in a Brownian System Driven by a Biharmonic Force]], J. Phys. Chem. B **117**, 13132-13144 (2013)
 +  * A. Sakurai and [[Yoshitaka Tanimura]], [[https://​journals.jps.jp/​doi/​abs/​10.7566/​JPSJ.82.033707|An approach to quantum transport based on reduced hierarchy equations of motion: Application to resonant tunneling diode]], J. Phys. Soc. Jpn **82**, 033707 (2013)
 +  * [[Daniel Wigger]], [[Doris Reiter]], V.M. Axt and T. Kuhn, [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.87.085301|Fluctuation properties of acoustic phonons generated by ultrafast optical excitation of a quantum dot]], Phys. Rev. B **87**, 085301 (2013)
 +  * Z.L. Xiang, S. Ashhab, J.Q. You, and [[Franco Nori]], [[https://​journals.aps.org/​rmp/​abstract/​10.1103/​RevModPhys.85.623|Hybrid quantum circuits: Superconducting circuits interacting with other quantum systems]], Rev. Mod. Phys. **85**, 623 (2013)
 +  * A. Miranowicz, M. Paprzycka, Y.X. Liu, J. Bajer, and [[Franco Nori]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.87.023809|Two-photon and three-photon blockades in driven nonlinear systems]], Phys. Rev. A **87**, 023809 (2013)
 +  * C. Wickles and [[Wolfgang Belzig]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.88.045308|Effective quantum theories for Bloch dynamics in inhomogeneous systems
 +with nontrivial band structure]],​ Phys. Rev. B **88**, 045308 (2013)
 +  * R. Schmidt, J.T. Stockburger,​ and [[Joachim Ankerhold]],​ [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.88.052321|Almost local generation of Einstein-Podolsky-Rosen entanglement in nonequilibrium open systems]], Phys. Rev. A **88**, 052321 (2013)
 +  * V. Gramich, B. Kubala, S. Rohrer, and [[Joachim Ankerhold]],​ [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.111.247002|From Coulomb-Blockade to Nonlinear Quantum Dynamics in a Superconducting Circuit with a Resonator]],​ Phys. Rev. Lett. **111**, 247002 (2013)
 +  * [[Andras Dombi]], [[Andras Vukics]], and [[Peter Domokos]], [[https://​iopscience.iop.org/​article/​10.1088/​0953-4075/​46/​22/​224010/​meta|Optical Bistability in Strong-Coupling Cavity QED with a Few Atoms]], ​ J. Phys. B Atom. Mol. Opt. Phys. **46**, 224010 (2013)
 +  * [[Stephan Schiller]] and Gerd Breitenbach,​ [[https://​onlinelibrary.wiley.com/​doi/​abs/​10.1002/​phbl.19990550509|Die Vermessung optischer Quantenzustände]],​ Phys. Bl. **55**, 39 (2013)
 +
 +=== 2012 ===
 +  * Simon Rips, Martin Kiffner, Ignacio Wilson-Rae, and [[Michael J. Hartmann]], [[https://​iopscience.iop.org/​article/​10.1088/​1367-2630/​14/​2/​023042|Steady-state negative Wigner functions of nonlinear nanomechanical oscillators]],​ New J. Phys. **14**, 023042 (2012)
 +  * R. Schmidt, S. Rohrer, [[Joachim Ankerhold]],​ and J.T. Stockburger,​ [[https://​dx.doi.org/​10.1088/​0031-8949/​2012/​T151/​014034|Cooling of quantum systems through optimal control and dissipation]],​ Phys. Script. **T151**, 014034 (2012)
 +  * Derek Harland, [[Mark Everitt]], [[Kae Nemoto]], [[Todd Tilma]], and TP Spiller, [[https://​doi.org/​10.1103/​PhysRevA.86.062117|Towards a complete and continuous Wigner function for an ensemble of spins or qubits]], Phys. Rev. A **86**, 062117 (2012)
 +
 +=== 2011 ===
 +  * A. Sakurai and [[Yoshitaka Tanimura]], [[https://​pubs.acs.org.ccindex.cn/​doi/​abs/​10.1021/​jp1095618|Does hbar play a role in multidimensional spectroscopy?​ Reduced hierarchy equations of motion approach to molecular vibrations]],​ J. Phys. Chem. A **115**, 4009-4022 (2011)
 +  * [[Doris Reiter]], [[Daniel Wigger]], J.M. Daniels, T. Papenkort, A. Vagov, V.M. Axt and T. Kuhn, [[https://​onlinelibrary.wiley.com/​doi/​full/​10.1002/​pssb.201000783|Fluctuation properties of phonons generated by ultrafast optical excitation of a quantum dot]], Phys. Status Solidi B 248, No. 4, 825-828 (2011)
 +  * [[Doris Reiter]], [[Daniel Wigger]], V.M. Axt and T. Kuhn, [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.84.195327|Generation and dynamics of phononic cat states after optical excitation of a quantum dot]], Phys. Rev. B. 84, 195327 (2011)
 +  * A. Bednorz and [[Wolfgang Belzig]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.83.052113|Fourth moments reveal the negativity of the Wigner function]], Phys. Rev. A **83**, 052113 (2011)
 +  * A.R.R. Carvalho, A. Kenfack, [[Fabricio Toscano]], J.M. Rost, and [[Alfredo Miguel Ozorio de Almeida]], [[https://​www.sciencedirect.com/​science/​article/​abs/​pii/​S0375960111012758?​via%3Dihub|Gaussian representation of extended quantum states]], Phys. Lett. A **376**, 19 (2011) ​
 +  * J.Q. You and [[Franco Nori]], [[https://​www.nature.com/​articles/​nature10122|Atomic physics and quantum optics using superconducting circuits]], Nature **474**, 589 (2011)
 +  * J. Ma, X. Wang, C. P. Sun, and [[Franco Nori]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0370157311002201|Quantum spin squeezing]],​ Phys. Rep. **509**, 89 (2011)
 +  * I. Buluta, S. Ashhab, and [[Franco Nori]], [[https://​iopscience.iop.org/​article/​10.1088/​0034-4885/​74/​10/​104401/​meta|Natural and artificial atoms for quantum computation]],​ Rep.. Prog. Phys. **74**, 104401 (2011)
 +  * [[Todd Tilma]] and [[Kae Nemoto]], [[https://​iopscience.iop.org/​article/​10.1088/​1751-8113/​45/​1/​015302|SU(N)-symmetric quasi-probability distribution functions]],​ J. Phys. A. Math. and Theor. **45**, 015302 (2011)
 +
 +=== 2010 ===
 +  * [[Mark Everitt]], WJ Munro, and TP Spiller, [[https://​www.sciencedirect.com/​science/​article/​pii/​S0375960110005700?​via%3Dihub|Quantum measurement with chaotic apparatus]],​ Phys. Lett. A **374**, 2809 (2010)
 +  * S. Ashhab and [[Franco Nori]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.81.042311|Qubit-oscillator systems in the ultrastrong-coupling regime and their potential for preparing nonclassical states]], Phys. Rev. A **81**, 042311 (2010)
 +  * Y.X. Liu, A. Miranowicz, Y.B. Gao, J. Bajer, C.P. Sun, and [[Franco Nori]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.82.032101|Qubit-induced phonon blockade as a signature of quantum behavior in nanomechanical resonators]],​ Phys. Rev. A **82**, 032101 (2010)
 +
 +=== 2009 ===
 +  * [[Mark Everitt]], WJ Munro, and TP Spiller, [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.79.032328|Quantum-classical crossover of a field mode]], Phys. Rev. A **79**, 032328 (2009)  ​
 +  * I.Buluta and [[Franco Nori]], [[https://​science.sciencemag.org/​content/​326/​5949/​108|Quantum Simulators]],​ Science **326**, 108 (2009)
 +
 +=== 2007 ===
 +  * [[Doris Reiter]], M. Glanemann, V.M. Axt and T. Kuhn, [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.75.205327|Spatiotemporal dynamics in optically excited quantum wire-dot systems: Capture, escape, and wave-front dynamics]], Phys. Rev. B. 75, 205327 ​ (2007)
 +
 +=== 2006 ===
 +  * [[Yoshitaka Tanimura]], [[https://​journals.jps.jp/​doi/​abs/​10.1143/​JPSJ.75.082001|Stochastic Liouville, Langevin, Fokker-Planck,​ and master equation approaches to quantum dissipative systems]], J. Phys. Soc. Jpn. **75**, 082001 (2006)
 +  * Brad A. Rowland, [[Robert Wyatt]], [[https://​doi.org/​10.1016/​j.cplett.2006.05.041|Local and non-local force analysis for Wigner function barrier scattering]] Chem. Phys. Lett. **426**, 209 (2006) ​
 +
 +=== 2005 ===
 +  * C. K. Zachos, D. B. Fairlie and T. L. Curtright, [[https://​doi.org/​10.1142/​5287|Quantum Mechanics in Phase Space. An Overview with Selected Papers]] (World Scientific Publishing Co Pte Ltd, 2005)
 +  * J.Q. You and [[Franco Nori]], [[https://​physicstoday.scitation.org/​doi/​10.1063/​1.2155757?​feed=most-cited|Superconducting circuits and quantum information]],​ Phys. Today **58**, 42 (2005)
 +
 +=== 2004 ===
 +  * [[Mark Everitt]], TD Clark, PB Stiffell, A Vourdas, JF Ralph, RJ Prance, and H Prance, [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.69.043804|Superconducting analogs of quantum optical phenomena: Macroscopic quantum superpositions and squeezing in a superconducting quantum-interference]],​ Phys. Rev. A **69**, 043804 (2004)
 +
 +=== 2003 ===
 +  * Kyungsun Na, [[Robert Wyatt]], [[https://​doi.org/​10.1238/​Physica.Regular.067a00169|Quantum Hydrodynamic Analysis of Decoherence]],​ Phys. Scr. **67**, 169 (2003)
 +
 +=== 2002 ===
 +  * Lorenzo Galleani and [[Leon Cohen]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0375960102011386|The Wigner distribution for classical systems]], Phys. Lett. A **302**, 149 (2002)
 +
 +=== 2001 ===
 +  * [[Peter Domokos]], P. Horak and H. Ritsch, [[https://​iopscience.iop.org/​article/​10.1088/​0953-4075/​34/​2/​306|Semiclassical Theory of Cavity-Assisted Atom Cooling]], ​ J. Phys. B **34**, 187 (2001)
 +  * [[Alexander Lvovsky]], H. Hansen, T. Aichele, O. Benson, J. Mlynek, and S. Schiller, [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.87.050402|Quantum state reconstruction of the single-photon Fock state]], Phys. Rev. Lett. **87**, 050402 (2001)
 +
 +=== 2000 ===
 +  * [[Giovanni Manfredi]] and M.R. Feix, [[https://​journals.aps.org/​pre/​abstract/​10.1103/​PhysRevE.62.4665|Entropy and Wigner functions]],​ Phys. Rev. E **62**, 4665 (2000)
 +
 +=== 1998 ===
 +  * [[Alfredo Miguel Ozorio de Almeida]], [[https://​www.sciencedirect.com/​science/​article/​abs/​pii/​S0370157397000707|The Weyl representation in classical and quantum mechanics]],​ Phys. Rep. **295**, 265 (1998)
 +  * G. Breitenbach,​ F. Illuminati, [[Stephan Schiller]], and J. Mlynek, [[https://​iopscience.iop.org/​article/​10.1209/​epl/​i1998-00456-2/​fulltext/​|Broadband detection of squeezed vacuum: A spectrum of quantum states]], Europhysics Letters **44**, 192 (1998)
 +
 +=== 1997 ===
 +  * S. Bose, K. Jacobs, and [[Peter Knight]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.56.4175|Preparation of nonclassical states in cavities with a moving mirror]], Phys. Rev. A **56**, 4175 (1997)
 +
 +
 +=== 1996 ===
 +  * S. Szabo, P. Adam, J. Janszky and [[Peter Domokos]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.53.2698|Construction of Quantum States of the Radiation Field by Discrete Coherent–State Superpositions]],​ Phys. Rev. A **53**, 2698 (1996)
 +  * [[Stephan Schiller]], G. Breitenbach,​ S. F. Pereira, T. Müller, and J. Mlynek, [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.77.2933|Quantum Statistics of the Squeezed Vacuum by Measurement of the Density Matrixin the Number State Representation]],​ Phys. Rev. Lett. **77**, 2933 (1996)
 +
 ==== Gravitation and High Energy Physics ====  ==== Gravitation and High Energy Physics ==== 
-=== 2019 ===+
 === 2018 === === 2018 ===
   * Alex E. Bernardini, Pedro Leal, and Orfeu Bertolami, [[https://​doi.org/​10.1088/​1475-7516/​2018/​02/​025|Quantum to classical transition in the Hořava-Lifshitz quantum cosmology]],​ JCAP**02**, 025 (2018)   * Alex E. Bernardini, Pedro Leal, and Orfeu Bertolami, [[https://​doi.org/​10.1088/​1475-7516/​2018/​02/​025|Quantum to classical transition in the Hořava-Lifshitz quantum cosmology]],​ JCAP**02**, 025 (2018)
 +
 === 2017 === === 2017 ===
   * Giovanni Manfredi, [[Omar Morandi]], Lazar Friedland, Tobias Jenke, and Hartmut Abele, [[https://​link.aps.org/​doi/​10.1103/​PhysRevD.95.025016|Chirped-frequency excitation of gravitationally bound ultracold neutrons.]],​ Phys. Rev. D **95**, 025016 (2017)   * Giovanni Manfredi, [[Omar Morandi]], Lazar Friedland, Tobias Jenke, and Hartmut Abele, [[https://​link.aps.org/​doi/​10.1103/​PhysRevD.95.025016|Chirped-frequency excitation of gravitationally bound ultracold neutrons.]],​ Phys. Rev. D **95**, 025016 (2017)
-=== 2016 ===+
 === 2015 === === 2015 ===
   * Alex E. Bernardini, Salomon S. Mizrahi, [[https://​doi.org/​10.1088/​0031-8949/​90/​7/​074011|Coherent quantum squeezing due to the phase space noncommutativity]],​ Phys. Scr.  **90**, 074011 (2015)   * Alex E. Bernardini, Salomon S. Mizrahi, [[https://​doi.org/​10.1088/​0031-8949/​90/​7/​074011|Coherent quantum squeezing due to the phase space noncommutativity]],​ Phys. Scr.  **90**, 074011 (2015)
 +
 +=== 1991 ===
 +  * Y. S. Kim and M. E. Noz, [[https://​doi.org/​10.1142/​1197|Phase Space Picture of Quantum Mechanics. Group Theoretical Approach]] (World Scientific, 1991)
 +
 +=== 1983 ===
 +  * P. Carruthers and F. Zachariasen,​ [[https://​link.aps.org/​doi/​10.1103/​RevModPhys.55.245|Quantum collision theory with phase-space distributions]],​ Rev. Mod. Phys. **55**, ​ 245 (1983)
 +  * V. I. Tatarskiĭ,​[[https://​doi.org/​10.1070/​PU1983v026n04ABEH004345|The Wigner representation of quantum mechanics]],​ Sov. Phys. Usp. **26**, 311 (1983)
 +
 +=== 1958 ===
 +  * G. A. Baker, Jr., [[https://​doi.org/​10.1103/​PhysRev.109.2198|Formulation of Quantum Mechanics Based on the Quasi-Probability Distribution Induced on Phase Space]], Phys. Rev. **109**, 2198 (1958)
 +
 ==== Atomic Physics and Quantum Optics ====  ==== Atomic Physics and Quantum Optics ==== 
 +
 === 2019 === === 2019 ===
 +  * [[Stefano Olivares]], Alessia Allevi, Giovanni Caiazzo, M. G. A. Paris, and Maria Bondani, [[https://​iopscience.iop.org/​article/​10.1088/​1367-2630/​ab4afb/​meta|Quantum tomography of light states by photon-number-resolving detectors]],​ New. J. Phys. **21**, 103045 (2019)
 +  * Dmitry V. Strekalov and [[Gerd Leuchs]], [[https://​link.springer.com/​chapter/​10.1007/​978-3-319-98402-5_3|Nonlinear Interactions and Non-classical Light]], Quant. Photon., 51 (2019)
 +  * Yosuke Hashimoto, Takeshi Toyama, Jun-ichi Yoshikawa, Kenzo Makino, Fumiya Okamoto, Rei Sakakibara, Shuntaro Takeda, Peter van Loock, and [[Akira Furusawa]], [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.123.113603|All-Optical Storage of Phase-Sensitive Quantum States of Light]], Phys. Rev. Lett. **123**, 113603 (2019)
 +  * R Gutierrez-Cuevas,​ M R Dennis, and [[Miguel A. Alonso]], [[https://​iopscience.iop.org/​article/​10.1088/​2040-8986/​ab2c52/​meta|Generalized Gaussian beams in terms of Jones vectors]], J. Opt. **21**, 084001 (2019)
 +
 === 2018 === === 2018 ===
 +  * H. Le Jeannic, A. Cavaillès, K. Huang, R. Filip, and [[Julien Laurat]], [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.120.073603|Slowing Quantum Decoherence by Squeezing in Phase Space]], Phys. Rev. Lett. **120**, 073603 (2018)
 +  * A. Cavaillès, H. Le Jeannic, J. Raskop, G. Guccione, D. Markham, E. Diamanti, M. D. Shaw, V. B. Verma, S. W. Nam, and [[Julien Laurat]], [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.121.170403|Demonstration of Einstein-Podolsky-Rosen Steering Using Hybrid Continuous- and Discrete-Variable Entanglement of Light]], Phys. Rev. Lett. **121**, 170403 (2018)
   * C. Flühmann and V. Negnevitsky and M. Marinelli and J. P. Home, [[https://​link.aps.org/​doi/​10.1103/​PhysRevX.8.021001|Sequential Modular Position and Momentum Measurements of a Trapped Ion Mechanical Oscillator]],​ Phys. Rev. X **8**, ​ 021001 (2018)   * C. Flühmann and V. Negnevitsky and M. Marinelli and J. P. Home, [[https://​link.aps.org/​doi/​10.1103/​PhysRevX.8.021001|Sequential Modular Position and Momentum Measurements of a Trapped Ion Mechanical Oscillator]],​ Phys. Rev. X **8**, ​ 021001 (2018)
 +  * [[Enno Giese]], Robert Fickler, Wuhong Zhang, Lixiang Chen, and Robert W. Boyd, [[https://​iopscience.iop.org/​article/​10.1088/​1402-4896/​aace12/​meta|Influence of pump coherence on the quantum properties of spontaneous parametric down-conversion]],​ Phys. Script. **93**, 084001 (2018)
 +  * Richard Birrittella,​ M. El Baz, and [[Christopher C. Gerry]], [[https://​www.osapublishing.org/​josab/​abstract.cfm?​uri=josab-35-7-1514|Photon catalysis and quantum state engineering ]], J. Opt. Soc. Amer. B **35**, 1514 (2018)
   * J. T. Mendonça, H. Terças, and A. Gammal, [[https://​link.aps.org/​doi/​10.1103/​PhysRevA.97.063610|Quantum Landau damping in dipolar Bose-Einstein condensates]],​ Phys. Rev. A **97**, 063610 (2018)   * J. T. Mendonça, H. Terças, and A. Gammal, [[https://​link.aps.org/​doi/​10.1103/​PhysRevA.97.063610|Quantum Landau damping in dipolar Bose-Einstein condensates]],​ Phys. Rev. A **97**, 063610 (2018)
-=== 2017 ===+
 === 2016 === === 2016 ===
 +  * C. Sparaciari, [[Stefano Olivares]], and M. G. A. Paris, [[http://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.93.023810|Gaussian-state interferometry with passive and active elements]], Phys. Rev. A **93**, 023810 (2016)
 +  * S. Cialdi, C. Porto, D. Cipriani, [[Stefano Olivares]], and M. G. A. Paris, [[http://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.93.043805|Full quantum state reconstruction of symmetric two-mode squeezed thermal states via spectral homodyne detection and a state-balancing detector]], Phys. Rev. A **93**, 043805 (2016)
 +  * Christian R Müller, Christian Peuntinger, Thomas Dirmeier, Imran Khan, Ulrich Vogl, Ch Marquardt, [[Gerd Leuchs]], Luis L Sánchez-Soto,​ Yong Siah Teo, Zdenek Hradil, Jaroslav Řeháček, [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.117.070801|Evading Vacuum Noise: Wigner Projections or Husimi Samples?]], Phys. Rev. Lett. **117**, 070801 (2016)
 +  * Kenzo Makino, Yosuke Hashimoto, Jun-ichi Yoshikawa, Hideaki Ohdan, Takeshi Toyama, Peter van Loock, and [[Akira Furusawa]], [[https://​advances.sciencemag.org/​content/​2/​5/​e1501772|Synchronization of Optical Photons for Quantum Information Processing]],​ Sci. Adv. **2**, e1501772 (2016) ​
   * D. Kienzler and C. Flühmann and V. Negnevitsky and H.-Y. Lo and M. Marinelli and D. Nadlinger and J. P. Home, [[https://​link.aps.org/​doi/​10.1103/​PhysRevLett.116.140402|Observation of Quantum Interference between Separated Mechanical Oscillator Wave Packets]], Phys. Rev. Lett **116**, ​ 140402 (2016)   * D. Kienzler and C. Flühmann and V. Negnevitsky and H.-Y. Lo and M. Marinelli and D. Nadlinger and J. P. Home, [[https://​link.aps.org/​doi/​10.1103/​PhysRevLett.116.140402|Observation of Quantum Interference between Separated Mechanical Oscillator Wave Packets]], Phys. Rev. Lett **116**, ​ 140402 (2016)
 +  * Juan  Mauricio Torres, Jozsef Zsolt Bernad, and [[Gernot Alber]], [[https://​link.springer.com/​article/​10.1007/​s00340-016-6382-3|Unambiguous atomic Bell measurement assisted by multiphoton states]], Appl. Phys. B **122**, 117 (2016)
 +
 === 2015 === === 2015 ===
-==== Condensed Matter: ​optical ​and transport ​properties of systems ​==== +  * C. Sparaciari, [[Stefano Olivares]], and M. G. A. Paris, [[https://​www.osapublishing.org/​josab/​abstract.cfm?​uri=josab-32-7-1354|Bounds to precision for quantum interferometry with Gaussian states and operations]],​ J. Opt. Soc. Am. B **32**, 1354 (2015) 
 +  * Richard Birrittella,​ Kezi Cheng, and [[Christopher C. Gerry]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0030401815004447?​via%3Dihub|Photon-Number Parity Oscillations in the Resonant Jaynes-Cummings Model]], Opt. Comm. **354**, 286 (2015)  
 +  * K. Huang, H. Le Jeannic, J. Ruaudel, V. B. Verma, M. D. Shaw, F. Marsili, S. W. Nam, E Wu, H. Zeng, Y.-C. Jeong, R. Filip, O. Morin, and [[Julien Laurat]], [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.115.023602|Optical Synthesis of Large-Amplitude Squeezed Coherent-State Superpositions with Minimal Resources]],​ Phys. Rev. Lett. **115**, 023602 (2015) 
 + 
 +=== 2014 === 
 +  * M. Esposito, F. Benatti, R. Floreanini, [[Stefano Olivares]], F. Randi, K. Titimbo, M. Pividori, F. Novelli, F. Cilento, F. Parmigiani, and D. Fausti, [[http://​iopscience.iop.org/​article/​10.1088/​1367-2630/​16/​4/​043004|Pulsed homodyne Gaussian quantum tomography with low detection efficiency]],​ New. J. Phys. **16**, 043004 (2014) 
 +  * Olivier Morin, Kun Huang, Jianli Liu, Hanna Le Jeannic, Claude Fabre, and [[Julien Laurat]], [[https://​www.nature.com/​articles/​nphoton.2014.137|Remote creation of hybrid entanglement between particle-like and wave-like optical qubits]], Nature Photon. **8**, 570 (2014) 
 + 
 +=== 2013 === 
 +  * A. Meda, [[Stefano Olivares]], I. P. Degiovanni, G. Brida, M. Genovese, and M. G. A. Paris, [[https://​www.osapublishing.org/​ol/​abstract.cfm?​uri=ol-38-16-3099|Revealing interference by continuous variable discordant states]], Optics Letters **38**, 3099 (2013) 
 +  * M. G. Genoni, M. L. Palma, T. Tufarelli, [[Stefano Olivares]], M. S. Kim, and M. G. A. Paris, [[http://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.87.062104|Detecting quantum non-Gaussianity via the Wigner function]], Phys. Rev. A **87**, 062104 (2013) 
 + 
 +=== 2012 === 
 +  * [[Stefano Olivares]], [[http://​link.springer.com/​article/​10.1140/​epjst/​e2012-01532-4|Quantum optics in the phase space - A tutorial on Gaussian states]]; Eur. Phys. J. Special Topics **203**, 3-24 (2012) 
 + 
 +=== 2011 === 
 +  * [[Stefano Olivares]] and M. G. A. Paris, [[http://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.107.170505|Fidelity matters: the birth of entanglement in the mixing of Gaussian states]], Phys. Rev. Lett. **107**, 170505 (2011) 
 + 
 +=== 2009 === 
 +  * S. Cho, [[Jonathan Petruccelli]] and [[Miguel A. Alonso]], [[https://​www.tandfonline.com/​doi/​full/​10.1080/​09500340903377766|Wigner functions for paraxial and nonparaxial fields]] J. Mod. Opt. **56**, 1843 (2009) 
 +  * V. D'​Auria,​ S. Fornaro, A. Porzio, S. Solimeno, [[Stefano Olivares]], and M. G. A. Paris, [[http://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.102.020502|Full characterization of Gaussian bipartite entangled states by a single homodyne detector]], Phys. Rev. Lett. **102**, 020502 (2009) 
 +  * R. Vasile, [[Stefano Olivares]], M. G. A. Paris, and S. Maniscalco, [[http://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.80.062324|Continuous-variable-entanglement dynamics in structured reservoirs]],​ Phys. Rev. A **80**, 062324 (2009) 
 + 
 +=== 2008 === 
 +  * Patrick Loughlin and [[Leon Cohen]], [[https://​www.tandfonline.com/​doi/​full/​10.1080/​09500340802220745|Approximate wave function from approximate non-representable Wigner distributions]],​ J.  Mod. Opt. **55**, 3379 (2008) 
 + 
 +=== 2007 === 
 +  * S. Maniscalco, [[Stefano Olivares]], and M. G. A. Paris, [[http://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.75.062119|Entanglement oscillations in non-Markovian quantum channels]], Phys. Rev. A **75**, 062119 (2007) 
 +  * [[Jonathan Petruccelli]] and [[Miguel A. Alonso]], [[https://​www.osapublishing.org/​josaa/​abstract.cfm?​uri=josaa-24-9-2590|Propagation of partially coherent fields through planar dielectric boundaries using angle-impact Wigner functions I. Two dimensions]] J. Opt. Soc. Am. A **24**, 2590 (2007) 
 + 
 + 
 + 
 + 
 +==== Condensed Matter: ​Optical ​and Transport ​properties of Systems ​==== 
 === 2019 === === 2019 ===
 +  * [[Dmitry Karlovets]],​ [[https://​iopscience.iop.org/​article/​10.1088/​1751-8121/​aaf9d8|On Wigner function of a vortex electron]], J. Phys. A: Math. Theor. **52**, 05LT01 (2019)
 +  * [[Thierry Goudon]] and Alexis F. Vasseur, [[https://​epubs.siam.org/​doi/​abs/​10.1137/​18M1184643|Statistical Stability for Transport in Random Media]], SIAM Multiscale Model. Simul. **17**, 507 (2019)
 +  * Matteo Acciai, Matteo Carrega, Jérôme Rech, Thibaut Jonckheere, [[Dario Ferraro]], Thierry Martin, and Maura Sassetti, [[https://​iopscience.iop.org/​article/​10.1088/​1742-6596/​1182/​1/​012003/​meta|Single-electron excitations and interactions in integer quantum Hall systems at ν = 2]], J. Phys. Conf. Ser. **1182**, 012003 (2019)
 +  * R. Bisognin, A. Marguerite, B. Roussel, M. Kumar, C. Cabart, C. Chapdelaine,​ A. Mohammad-Djafari,​ J.-M. Berroir, E. Bocquillon, B. Plaçais, A. Cavanna, U. Gennser, Y. Jin, [[Pascal Degiovanni]],​ and [[Gwendal Fève]], [[https://​www.nature.com/​articles/​s41467-019-11369-5|Quantum tomography of electrical currents]], Nat. Comm. **10**, 3379 (2019)
 +  * [[Mihail (Mixi) Nedjalkov]],​ [[Josef Weinbub]], Mauro Ballicchia, [[Siegfried Selberherr]],​ [[Ivan Dimov]], and [[David K. Ferry]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.99.014423|Wigner equation for general electromagnetic fields: The Weyl-Stratonovich transform]],​ Phys. Rev. B **99**, ​ 014423 (2019)
 +  * Mauro Ballicchia, [[David K. Ferry]], [[Mihail (Mixi) Nedjalkov]],​ [[Josef Weinbub]], [[https://​www.mdpi.com/​2076-3417/​9/​7/​1344|Investigating Quantum Coherence by Negative Excursions of the Wigner Quasi-Distribution]],​ Appl. Sci. **9**, 1344 (2019)
 +  * Martin Koppenhöfer,​ [[Christoph Bruder]], and Niels Lörch, [[https://​arxiv.org/​abs/​1906.05126|Heralded dissipative preparation of nonclassical states in a Kerr oscillator]],​ arXiv (2019)
 +  * Niels Lörch, Yaxing Zhang, [[Christoph Bruder]], and M. I. Dykman, [[https://​journals.aps.org/​prresearch/​abstract/​10.1103/​PhysRevResearch.1.023023|Quantum state preparation for coupled period tripling oscillators]],​ Phys. Rev. Res. **1**, 023023 (2019)
 +  * David Picconi, Jeffrey A. Cina, and [[Irene Burghardt]],​ [[https://​aip.scitation.org/​doi/​10.1063/​1.5082650|Quantum dynamics and spectroscopy of dihalogens in solid matrices. I. Efficient simulation of the photodynamics of the embedded I2Kr18 cluster using the G-MCTDH method]], J. Chem. Phys. **150**, 064111 (2019)
 +  * David Picconi and [[Irene Burghardt]],​ [[https://​pubs.rsc.org/​en/​content/​articlehtml/​2019/​fd/​c9fd00065h|Time-resolved spectra of I2 in a krypton crystal by G-MCTDH simulations:​ nonadiabatic dynamics, dissipation and environment driven decoherence]],​ Farad. Discuss. (2019)
 +  * Robert Binder and [[Irene Burghardt]],​ [[https://​pubs.rsc.org/​en/​content/​articlehtml/​2019/​fd/​c9fd00066f|First-principles quantum simulations of exciton diffusion on a minimal oligothiophene chain at finite temperature]],​ Farad. Discuss. (2019)
 +  * David Picconi and [[Irene Burghardt]],​ [[https://​aip.scitation.org/​doi/​full/​10.1063/​1.5099983|Open system dynamics using Gaussian-based multiconfigurational time-dependent Hartree wavefunctions:​ Application to environment-modulated tunneling]],​ J. Chem. Phys. **150**, 224106 (2019)
 +  * [[Giovanni Manfredi]], Paul-Antoine Hervieux, and Jerome Hurst, [[https://​link.springer.com/​article/​10.1007/​s41614-019-0034-0|Phase-space modeling of solid-state plasmas]], Rev. Mod. Plasm. Phys. **3**, 13 (2019)
 +
 === 2018 === === 2018 ===
 +  * Alexandre Roulet and [[Christoph Bruder]], [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.121.053601|Synchronizing the Smallest Possible System]], Phys. Rev. Lett. **121**, 053601 (2018)
 +  * Ehud Amitai, Martin Koppenhöfer,​ Niels Lörch, and [[Christoph Bruder]], [[https://​journals.aps.org/​pre/​abstract/​10.1103/​PhysRevE.97.052203|Quantum effects in amplitude death of coupled anharmonic self-oscillators]],​ Phys. Rev. E **97**, 052203 (2018)
 +  * Tianji Ma, Matteo Bonfanti, Pierre Eisenbrandt,​ Rocco Martinazzo, and [[Irene Burghardt]],​ [[https://​aip.scitation.org/​doi/​full/​10.1063/​1.5062608|Multi-configurational Ehrenfest simulations of ultrafast nonadiabatic dynamics in a charge-transfer complex ]], J. Chem. Phys. **149**, 244107 (2018)
 +  * [[Luigi Barletti]], Giovanni Frosali, and Elisa Giovanni, [[https://​www.tandfonline.com/​doi/​full/​10.1080/​23324309.2018.1520732|Adding Decoherence to the Wigner Equation]], J. Comp. Theor. Trans. **47**, 209 (2018)
 +  * [[Josef Weinbub]], Mauro Ballicchia, and [[Mihail (Mixi) Nedjalkov]],​ [[https://​onlinelibrary.wiley.com/​doi/​full/​10.1002/​pssr.201800111|Electron Interference in a Double‐Dopant Potential Structure]],​ Phys. Stat. Sol. RRL **12**, ​ 1800111 (2018)
 +  * Mauro Ballicchia, [[Josef Weinbub]], [[Mihail (Mixi) Nedjalkov]],​ [[https://​pubs.rsc.org/​en/​content/​articlelanding/​2018/​NR/​C8NR06933F#​!divAbstract|Electron Evolution Around a Repulsive Dopant in a Quantum Wire: Coherence Effects]], Nanoscale **10**, 23037 (2018)
 +
 === 2017 === === 2017 ===
 +  * Talitha Weiss, Stefan Walter, and [[Florian Marquardt]],​ [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.95.041802|Quantum-coherent phase oscillations in synchronization]],​ Phys. Rev. A **95**, 041802(R) (2017)
 +  * [[Dmitry Karlovets]],​[[https://​link.springer.com/​article/​10.1007/​JHEP03(2017)049|Scattering of wave packets with phases]], J. High Energy Physics **2017**, 49 (2017)
 +  * [[Dmitry Karlovets]] and V.G. Serbo, [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.119.173601|Possibility to Probe Negative Values of a Wigner Function in Scattering of a Coherent Superposition of Electronic Wave Packets by Atoms]], Phys. Rev. Lett. **119**, 173601 (2017)
   *  [[Maciej Woloszyn]] and [[Bartlomiej Spisak]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.96.075440|Dissipative transport of thermalized electrons through a nanodevice]],​ Phys. Rev. B **96**, ​ 075440 (2017)   *  [[Maciej Woloszyn]] and [[Bartlomiej Spisak]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.96.075440|Dissipative transport of thermalized electrons through a nanodevice]],​ Phys. Rev. B **96**, ​ 075440 (2017)
 +  * [[Paul Ellinghaus]],​ [[Josef Weinbub]], [[Mihail (Mixi) Nedjalkov]] and [[Siegfried Selberherr]],​ [[https://​onlinelibrary.wiley.com/​doi/​abs/​10.1002/​pssr.201700102|Analysis of Lense-Governed Wigner Signed Particle Quantum Dynamics]], Phys. Stat. Sol. RRL **11**, 1700102 (2017).
   * T. Ikeda and Y. Tanimura, [[https://​doi.org/​10.1063/​1.4989537|Probing photoisomerization processes by    * T. Ikeda and Y. Tanimura, [[https://​doi.org/​10.1063/​1.4989537|Probing photoisomerization processes by 
 means of multi-dimensional electronic spectroscopy:​ The multi-state quantum hierarchal Fokker-Planck Equation approach]], J. Chem. Phys. **146**, 014102 (2017) means of multi-dimensional electronic spectroscopy:​ The multi-state quantum hierarchal Fokker-Planck Equation approach]], J. Chem. Phys. **146**, 014102 (2017)
Line 108: Line 357:
   * [[Gerald J Iafrate]], V. N. Sokolov, and J. B. Krieger, [[https://​link.aps.org/​doi/​10.1103/​PhysRevB.96.144303|Quantum transport and the Wigner distribution function for Bloch electrons in spatially homogeneous electric and magnetic fields]], Phys. Rev. B **96**, 144303 (2017)   * [[Gerald J Iafrate]], V. N. Sokolov, and J. B. Krieger, [[https://​link.aps.org/​doi/​10.1103/​PhysRevB.96.144303|Quantum transport and the Wigner distribution function for Bloch electrons in spatially homogeneous electric and magnetic fields]], Phys. Rev. B **96**, 144303 (2017)
   * * A.S. Larkin, V.S. Filinov, V.E. Fortov, [[https://​doi.org/​10.1002/​ctpp.201700082|Pauli blocking by effective pair pseudopotential in degenerate Fermi systems of particles]],​ Contrib. Plasma Phys. **57**, 187506 (2017)   * * A.S. Larkin, V.S. Filinov, V.E. Fortov, [[https://​doi.org/​10.1002/​ctpp.201700082|Pauli blocking by effective pair pseudopotential in degenerate Fermi systems of particles]],​ Contrib. Plasma Phys. **57**, 187506 (2017)
 +
 === 2016 === === 2016 ===
 +  * [[Christian B. Mendl]], Jianfeng Lu, and Jani Lukkarinen, [[https://​journals.aps.org/​pre/​abstract/​10.1103/​PhysRevE.94.062104|Thermalization of oscillator chains with onsite anharmonicity and comparison with kinetic theory]], Phys. Rev. E **94**, 062104 (2016)
 +  * Vittorio Peano, Martin Houde, [[Florian Marquardt]],​ and Aashish A. Clerk, [[https://​journals.aps.org/​prx/​abstract/​10.1103/​PhysRevX.6.041026|Topological Quantum Fluctuations and Traveling Wave Amplifiers]],​ Phys. Rev. X **6**, 041026 (2016)
   * R. Grossmann, A. Sakurai, ​ and Y. Tanimura, [[https://​journals.jps.jp/​doi/​10.7566/​JPSJ.85.034803|Electron pumping under non-Markovian dissipation:​ The role of the self-consistent field]], J. Phys. Soc. Jpn. **85**, 034803 (2016)   * R. Grossmann, A. Sakurai, ​ and Y. Tanimura, [[https://​journals.jps.jp/​doi/​10.7566/​JPSJ.85.034803|Electron pumping under non-Markovian dissipation:​ The role of the self-consistent field]], J. Phys. Soc. Jpn. **85**, 034803 (2016)
   * J. T. Mendonça and A Serbeto, [[https://​doi.org/​10.1088/​0031-8949/​91/​9/​095601|Photon and electron Landau ​   * J. T. Mendonça and A Serbeto, [[https://​doi.org/​10.1088/​0031-8949/​91/​9/​095601|Photon and electron Landau ​
 damping in quantum plasmas]], Phys. Scr. ** 91**, 095601 ​ (2016) damping in quantum plasmas]], Phys. Scr. ** 91**, 095601 ​ (2016)
 +  * Y. P. Kalmykov, ​ W. T. Coffey and S. V. Titov, [[ https://​doi.org/​10.1002/​9781119290971.ch2|Spin relaxation in phase space]], Adv. Chem. Phys.**161**,​ 41 (2016)
 +
 === 2015 === === 2015 ===
 +  * [[Mihail (Mixi) Nedjalkov]],​ [[Josef Weinbub]], [[Paul Ellinghaus]],​ and [[Siegfried Selberherr]],​ [[https://​link.springer.com/​article/​10.1007%2Fs10825-015-0732-y|The Wigner Equation in the Presence of Electromagnetic Potentials]],​ J. Comp. Electron. **14**, 888 (2015)
 +  * [[Olafur Jonasson]] and [[Irena Knezevic]], [[https://​link.springer.com/​article/​10.1007%2Fs10825-015-0734-9|Dissipative transport in superlattices within the Wigner function formalism]],​ J. Comp. Electron. **14**, 879 (2015)
   * Y. Tanimura, [[https://​aip.scitation.org/​doi/​10.1063/​1.4916647|Real-Time and Imaginary-Time Quantum Hierarchal Fokker-Planck Equations]],​ J. Chem. Phys. **142**, 144110 (2015)   * Y. Tanimura, [[https://​aip.scitation.org/​doi/​10.1063/​1.4916647|Real-Time and Imaginary-Time Quantum Hierarchal Fokker-Planck Equations]],​ J. Chem. Phys. **142**, 144110 (2015)
 +
 +=== 2014 ===
 +  * Pierrat, Romain and Ambichl, Philipp and Gigan, Sylvain and Haber, Alexander and Carminati, Rémi and [[Stefan Rotter]], [[https://​www.pnas.org/​content/​111/​50/​17765.short|Invariance Property of Wave Scattering Through Disordered Media]], Proceedings of the National Academy of Sciences **111**, 17765 (2014)
 +  * N. Crouseilles and [[Giovanni Manfredi]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0010465513001963|Asymptotic preserving schemes for the Wigner-Poisson-BGK equations in the diffusion limit]], Comp. Phys. Comm. **185**, 448 (2014)
 +
 +=== 2013 ===
 +  * [[Dario Ferraro]], A. Feller, A. Ghibaudo, E. Thibierge, E. Bocquillon, [[Gwendal Fève]], Ch. Grenier, and [[Pascal Degiovanni]],​ [[https://​journals.aps.org/​prb/​pdf/​10.1103/​PhysRevB.88.205303|Wigner function approach to single electron coherence in quantum Hall edge channels]], Phys. Rev. B **88**, 205303 (2013)
 +  * [[Xavier Oriols]] and [[David K. Ferry]], [[https://​link.springer.com/​article/​10.1007%2Fs10825-013-0461-z|Quantum Transport Beyond DC]], J. Comp. Electron. **12**, 317 (2013)
 +  * Ansgar Jüngel, [[Nicola Zamponi]], [[http://​dx.doi.org/​10.4310/​CMS.2013.v11.n3.a7|Two spinorial drift-diffusion models for quantum electron transport in graphene]], COMMUN. MATH. SCI. **11**, 807 (2013)
 +
 +
 +=== 2012 ===
 +  * [[Omar Morandi]] and [[Ferdinand Schürrer]],​ [[https://​iopscience.iop.org/​article/​10.1088/​1751-8113/​44/​26/​265301|Wigner model for quantum transport in graphene]], J. Phys. A: Math. Theor. **44**, 265301 (2012)
 +  * [[Nicola Zamponi]], [[https://​www.aimsciences.org/​article/​doi/​10.3934/​krm.2012.5.203|Some fluid-dynamic models for quantum electron transport in graphene via entropy minimization]],​ Kinet. Relat. Models **5**, 203 (2012)
 +
 +=== 2011 ===
 +  * [[Nicola Zamponi]] and [[Luigi Barletti]], [[https://​onlinelibrary.wiley.com/​doi/​full/​10.1002/​mma.1403|Quantum Electronic Transport in Graphene: A Kinetic and Fluid-Dynamic Approach]], Mathematical Methods in the Applied Sciences **34**, 807 (2011)
 +  * [[Omar Morandi]] and [[Ferdinand Schürrer]],​ [[http://​caim.simai.eu/​index.php/​caim/​article/​view/​360|Wigner model for Klein tunneling in graphene]], Comm. Appl. Indust. Math. **2**, (2011)
 +  * [[Nicola Zamponi]], [[Luigi Barletti]], [[ https://​doi.org/​10.1002/​mma.1403|Quantum electronic transport in graphene: A kinetic and fluid‐dynamic approach]], MATH METHOD APPL SCI **34** 807 (2011)
 +  * [[Stefan Rotter]] and Ambichl, Philipp and Libisch, Florian, [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.106.120602|Generating Particlelike Scattering States in Wave Transport]]",​ Physical Review Letters **106**, 120602 (2011)
 +
 +=== 2010 ===
 +  * R. Jasiak, [[Giovanni Manfredi]], and Paul-Antoine Hervieux, [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.81.241401|Electron Thermalization and Quantum Decoherence in Thin Metal films]], Phys. Rev. B **81**, 241401(R) (2010)
 +
 +=== 2009 ===
 +  * [[Omar Morandi]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.80.024301|Multiband Wigner-function formalism applied to the Zener band transition in a semiconductor]],​ Phys. Rev. B **80**, 024301 (2009)
 +  * R. Jasiak, [[Giovanni Manfredi]], and Paul-Antoine Hervieux, [[https://​iopscience.iop.org/​article/​10.1088/​1367-2630/​11/​6/​063042|Quantum-classical transition in the electron dynamics of thin metal films]], New J. Phys. **11**, 063042 (2009)
 +
 +=== 2008 ===
 +  * F. Haas, B. Eliasson, P. K. Shukla, and [[Giovanni Manfredi]], [[https://​journals.aps.org/​pre/​abstract/​10.1103/​PhysRevE.78.056407|Phase-space structures in quantum-plasma wave turbulence]],​ Phys. Rev. E **78**, 056407 (2008)
 +
 +=== 2005 ===
 +  * J. B. Krieger, A. A. Kiselev, and [[Gerald J Iafrate]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.72.195201|Quantum transport for a Bloch electron quasiparticle in an inhomogeneous electric field scattering from a random distribution of impurities: A Wigner approach]], Phys. Rev. B **72**, 195201 (2005) ​
 +
 +=== 2001 ===
 +  * M. Levanda and [[Victor Fleurov]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0003491601961706?​via%3Dihub|A Wigner Quasi-distribution Function for Charged Particles in Classical Electromagnetic Fields]], Ann. Phys. **292**, 199 (2001)
 +
 +
 +
 +=== 1988 ===
 +  * [[Gerald J Iafrate]], [[https://​link.springer.com/​chapter/​10.1007%2F978-1-4899-2382-0_16|Quantum Transport and the Wigner Function]], The Physics of Submicron Semiconductor Devices, NATO ASI Series **180**, 521 (1988)
 +
 +==== Engineering (Acoustics, Electronics,​ Seismology, Signals, etc.) ==== 
 +
 +=== 2019 ===
 +  * [[Joon-Ho Lee]], [[Mincheol Shin]], and Jeong Hyeon Seo, [[https://​aip.scitation.org/​doi/​full/​10.1063/​1.5085569|Performance limitations of nanowire resonant-tunneling transistors with steep switching analyzed by Wigner transport simulation]],​ J. Appl. Phys. **125**, 174502 (2019)
 +  * R.R. Sharma, A. Kalyani, ​ and [[Ram Bilas Pachori]], [[https://​doi.org/​10.1007/​s11760-019-01549-7|An empirical wavelet transform-based approach for cross-terms-free Wigner–Ville distribution]],​ SIViP **2019**, 1 (2019)
 +  * Arnab K. Majee, Adithya Kommini, and [[Zlatan Aksamija]], [[https://​onlinelibrary.wiley.com/​doi/​full/​10.1002/​andp.201800510|Electronic Transport and Thermopower in 2D and 3D Heterostructures—A Theory Perspective]],​ Ann. Phys. **531**, 1800510 (2019)
 +  * R.R. Sharma, Avinash Kalyani, and [[Ram Bilas Pachori]], [[https://​link.springer.com/​article/​10.1007%2Fs11760-019-01549-7|An empirical wavelet transform-based approach for cross-terms-free Wigner–Ville distribution]],​ Sig. Imag. Vid. Proc. (2019)
 +
 +=== 2018 ===
 +  * [[Kyoung-Youm Kim]], ​ [[Ting-wei Tang]], and Saehwa Kim, [[https://​aip.scitation.org/​doi/​full/​10.1063/​1.5055686|Accuracy balancing for the simulation of gate-all-around junctionless nanowire transistors using discrete Wigner transport equation ]], AIP Adv. **8**, 115105 (2018)
 +  * Rita Claudia Iotti and [[Fausto Rossi]], [[https://​www.mdpi.com/​1099-4300/​20/​10/​726|Microscopic Theory of Energy Dissipation and Decoherence in Solid-State Quantum Devices: Need for Nonlocal Scattering Models ]], Entropy **20**, 726 (2018)
 +  * [[Mihail (Mixi) Nedjalkov]],​ [[Paul Ellinghaus]],​ [[Josef Weinbub]], Toufik Sadi, Asen Asenov, [[Ivan Dimov]], and [[Siegfried Selberherr]],​ [[https://​www.sciencedirect.com/​science/​article/​pii/​S0010465518300821?​via%3Dihub|Stochastic Analysis of Surface Roughness Models in Quantum Wires]], Comp. Phys. Commun. **228**, 30 (2018)
 +  * [[David K. Ferry]] and Ian Welland, [[https://​link.springer.com/​article/​10.1007%2Fs10825-017-1094-4|Relativistic Wigner Functions in Transition Metal Dichalcogenides]],​ J. Comp. Electron. **17**, 110 (2018)
 +  * [[Gabriele Gradoni]], L. R. Arnaut, [[Stephen Creagh]], [[Gregor Tanner]], M. H. Baharuddin, C. Smartt, and D. W. P. Thomas, [[https://​ieeexplore.ieee.org/​document/​8046114/​authors#​authors|Wigner-Function-Based Propagation of Stochastic Field Emissions From Planar Electromagnetic Sources]], IEEE T. Electromag. Compa. **60**, 580 (2018)
 +  * R.R. Sharma and R.B. Pachori, [[https://​doi.org/​10.1007/​s00034-018-0846-0|Improved eigenvalue decomposition-based approach for reducing cross-terms in Wigner-Ville distribution]],​ Circuits Syst Signal Process **37**, 3330 (2018)
 +  * Khadija A. Khair, [[Shaikh S. Ahmed]], [[https://​ieeexplore.ieee.org/​abstract/​document/​8605839/​authors#​authors|Role of Interfacial and Intrinsic Coulomb Impurities in Monolayer MoS2 FETs]], Proc. IEEE Nanotechnology Materials and Devices Conference (NMDC), (2018)
 +  * R.R. Sharma and [[Ram Bilas Pachori]], [[https://​link.springer.com/​article/​10.1007/​s00034-018-0846-0|Improved eigenvalue decomposition-based approach for reducing cross-terms in Wigner-Ville distribution]],​ Circ. Sys. Sig. Proc. **37**, 3330 (2018)
 +  * Chenglong Bao, George Barbastathis,​ Hui Ji, Zuowei Shen and [[Zhengyun Zhang]], [[https://​epubs.siam.org/​doi/​abs/​10.1137/​17M1124097|Coherence Retrieval Using Trace Regularization]],​ SIAM J. Imag. Sci. **11**, 679 (2018)
 +
 +=== 2017 ===
 +  * [[Maciej Woloszyn]] and [[Bartlomiej Spisak]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.96.075440|Dissipative transport of thermalized electrons through a nanodevice]],​ Phys. Rev. B **96**, 075440 (2017)  ​
 +  * [[Joon-Ho Lee]] and [[Mincheol Shin]], [[https://​ieeexplore.ieee.org/​document/​8013152|Quantum transport simulation of nanowire resonant tunneling diodes based on a Wigner function model with spatially dependent effective masses]], IEEE T. Nanotech. **16**, 1028 (2017)
 +  * Rita Claudia Iotti and [[Fausto Rossi]], [[https://​link.springer.com/​article/​10.1140/​epjb/​e2017-80462-3|Phonon-induced dissipation and decoherence in solid-state quantum devices: Markovian versus non-Markovian treatments]],​ Europ. Phys. J. B **90**, 250 (2017)
 +  * Rita Claudia Iotti, Fabrizio Dolcini and [[Fausto Rossi]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.96.115420|Wigner-function formalism applied to semiconductor quantum devices: Need for nonlocal scattering models]], Phys. Rev. B **96**, 115420 (2017)
 +  * [[Joon-Ho Lee]] and [[Mincheol Shin]], [[https://​www.ingentaconnect.com/​contentone/​asp/​jctn/​2017/​00000014/​00000003/​art00013|Interplay Between a Gaussian Wave Packet and a Non-Reflecting Potential Analyzed Using the Wigner Equation]], J. Comput. Theor. Nanosci. **14**, 1329 (2017)
 +  * Khadija A. Khair, [[Shaikh S. Ahmed]], [[https://​ieeexplore.ieee.org/​abstract/​document/​8117451|Effects of uniaxial strain on polar optical phonon scattering and electron transport in monolayer MoS2 FETs]], Proc. IEEE  International Conference on Nanotechnology (NANO), (2017)
 +  * Adithya Kommini and [[Zlatan Aksamija]], [[https://​iopscience.iop.org/​article/​10.1088/​1361-648X/​aaa110/​meta|Thermoelectric properties of periodic quantum structures in the Wigner–Rode formalism]],​ J. Phys. Cond. Matt. **30**, 044004 (2017)
 +  * [[Zlatan Aksamija]], [[https://​www.taylorfrancis.com/​books/​e/​9781315108223|Nanophononics:​ Thermal Generation, Transport, and Conversion at the Nanoscale]] (Jenny Stanford Publishing, 2017)
 +  * [[Zhengyun Zhang]], Chenglong Bao, Hui Ji, Zuowei Shen, George Barbastathis,​ [[https://​doi.org/​10.1364/​JOSAA.34.002025|Apparent coherence loss in phase space tomography]],​ J. Opt. Soc. Am. A **34**, 2025 (2017)
 +
 +=== 2016 ===
 +  * U. Kaczor, B. Klimas, D. Szydlowski, [[Maciej Woloszyn]], and [[Bartlomiej Spisak]], [[https://​www.degruyter.com/​view/​j/​phys.2016.14.issue-1/​phys-2016-0036/​phys-2016-0036.xml|Phase-space description of the coherent state dynamics in a small one-dimensional system]], Open Phys. **14**, 354 (2016)  ​
 +  * R.B. Pachori and A. Nishad, [[https://​doi.org/​10.1016/​j.sigpro.2015.07.026|Cross-terms reduction in Wigner-Ville distribution using tunable-Q wavelet transform]],​ Signal Process **120**, 288 (2016)
 +  * Rita Claudia Iotti, Fabrizio Dolcini, Arianna Montorsi and [[Fausto Rossi]], [[https://​link.springer.com/​article/​10.1007/​s10825-016-0858-6|Electron–phonon dissipation in quantum nanodevices]],​ J. Comput. Electron. **15**, 1170 (2016)
 +  * [[Shaikh S. Ahmed]], et al., [[https://​ieeexplore.ieee.org/​abstract/​document/​7853846/​authors#​authors|Multiscale-multiphysics modeling of nonclassical semiconductor devices]], Proc. International Conference on Electrical and Computer Engineering (ICECE), (2016)
 +  * [[Ram Bilas Pachori]] and A. Nishad, [[https://​www.sciencedirect.com/​science/​article/​pii/​S0165168415002637|Cross-terms reduction in Wigner-Ville distribution using tunable-Q wavelet transform]],​ Sig. Proc. **120**, 288 (2016)
 +
 +=== 2015 ===
 +  * [[Bartlomiej Spisak]], [[Maciej Woloszyn]], D. Szydlowski, [[https://​link.springer.com/​article/​10.1007/​s10825-015-0733-x|Dynamical localisation of conduction electrons in one-dimensional disordered systems]], J. Comput. Electron. **14**, 916 (2015) ​
 +  * Roberto Rosati, Fabrizio Dolcini and [[Fausto Rossi]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.92.235423|Electron-phonon coupling in metallic carbon nanotubes: Dispersionless electron propagation despite dissipation]],​ Phys. Rev. B **92**, 235423 (2015)
 +
 +=== 2014 ===
 +  * [[Carlo Jacoboni]] and [[Paolo Bordone]], [[https://​link.springer.com/​article/​10.1007/​s10825-013-0510-7|Wigner transport equation with finite coherence length]], J. Comp. Electron. **13**, 257 (2014)
 +  * [[Olafur Jonasson]] and [[Irena Knezevic]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.90.165415|Coulomb-driven terahertz-frequency intrinsic current oscillations in a double-barrier tunneling structure]],​ Phys. Rev. B **90**, 165415 (2014)
 +  * [[Gabriele Gradoni]], [[Stephen Creagh]], and [[Gregor Tanner]], [[https://​ieeexplore.ieee.org/​document/​6899092|A Wigner Function Approach for Describing the Radiation of Complex Sources]], Proc. IEEE International Symposium on Electromagnetic Compatibility (EMC) (2014)
 +  * [[Gabriele Gradoni]], [[Stephen Creagh]], and [[Gregor Tanner]], [[https://​ieeexplore.ieee.org/​document/​6931029|Radiation of complex sources in reflecting environments:​ A Wigner function approach]], Proc. of IEEE International Symposium on Electromagnetic Compatibility (EMC) (2014)
 +  * J.M. Sellier, S. Amoroso, [[Mihail (Mixi) Nedjalkov]],​ [[Siegfried Selberherr]],​ Asen Asenov, and [[Ivan Dimov]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0378437113011862?​via%3Dihub|Electron Dynamics in Nanoscale Transistors by Means of Wigner and Boltzmann Approaches]],​ Physica A **398**, 194 (2014)
 +
 +=== 2013 ===
 +  * Rosati, Roberto and Dolcini, Fabrizio and Iotti, Rita Claudia and [[Fausto Rossi]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.88.035401|Wigner-function formalism applied to semiconductor quantum devices: failure of the conventional boundary condition scheme]], Phys. Rev. B **88**, 035401 (2013)
 +  * P. Jain and [[Ram Bilas Pachori]], [[https://​www.sciencedirect.com/​science/​article/​abs/​pii/​S0016003213000069|Marginal energy density over the low frequency range as a feature for voiced/​non-voiced detection in noisy speech signals]], J. Frank. Ins. **350**, 678 (2013)
 +  * V. Bajaj and [[Ram Bilas Pachori]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0169260713002265|Automatic classification of sleep stages based on the time-frequency image of EEG signals]], Comp. Meth. Prog. Biomed. **112**, 320 (2013)
 +  * Lei Tian, [[Zhengyun Zhang]], [[Jonathan Petruccelli]],​ and George Barbastathis,​ [[https://​doi.org/​10.1364/​OE.21.010511|Wigner function measurement using a lenslet array]], Opt. Express **21**, 10511 (2013)
 +  * D. Szydlowski, [[Maciej Woloszyn]], and [[Bartlomiej Spisak]], [[https://​iopscience.iop.org/​article/​10.1088/​0268-1242/​28/​10/​105022/​pdf|Phase-space description of wave packet approach to electronic transport in nanoscale systems]], Semicond. Sci. Technol. **28**, 105022 (2013) ​
 +  * P. Wójcik, J. Adamowski, [[Maciej Woloszyn]], and [[Bartlomiej Spisak]], [[https://​aip.scitation.org/​doi/​abs/​10.1063/​1.4811836?​journalCode=apl|Spin filter effect at room temperature in GaN/GaMnN ferromagnetic resonant tunnelling diode]], Appl. Phys. Lett. **102**, 242411 (2013) ​
 +
 +=== 2012 ===
 +  * P. Wojcik, J. Adamowski, [[Maciej Woloszyn]], and [[Bartlomiej Spisak]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.86.165318|Intrinsic oscillations of spin current polarization in a paramagnetic resonant tunneling diode]], Phys. Rev. B **86**, 165318 (2012) ​
 +  * P. Wojcik, [[Bartlomiej Spisak]], [[Maciej Woloszyn]], and J. Adamowski, [[https://​iopscience.iop.org/​article/​10.1088/​0268-1242/​27/​11/​115004/​meta|Hysteresis loops of spin-dependent electronic current in a paramagnetic resonant tunnelling diode]], Semicond. Sci. Technol. **27**, 115004 (2012) ​
 +  * P. Wojcik, [[Bartlomiej Spisak]], [[Maciej Woloszyn]], J. Adamowski, [[https://​aip.scitation.org/​doi/​10.1063/​1.4729895|Tuning of terahertz intrinsic oscillations in asymmetric triple-barrier resonant tunneling diodes]], J. Appl. Phys. **111**, 124310 (2012) ​
 +
 +=== 2011 ===
 +  * [[Sylvain Barraud]], [[https://​aip.scitation.org/​doi/​10.1063/​1.3654143|Dissipative quantum transport in silicon nanowires based on Wigner transport equation]], J. Appl. Phys. **110**, 093710 (2011)
 +
 +=== 2010 ===
 +  * [[Mihail (Mixi) Nedjalkov]],​ [[Hans Kosina]], and Philipp Schwaha, [[https://​link.springer.com/​article/​10.1007%2Fs10825-010-0316-9|Device Modeling in the Wigner Picture]], J. Comp. Electron. **9**, 218 (2010)
 +  * P. Wojcik, [[Bartlomiej Spisak]], [[Maciej Woloszyn]], J. Adamowski, [[https://​iopscience.iop.org/​article/​10.1088/​0268-1242/​25/​12/​125012|Intrinsic current oscillations in an asymmetric triple-barrier resonant tunnelling diode]], Semicond. Sci. Technol. **25**, 125012 (2010) ​
 +
 +=== 2009 ===
 +  * [[Sylvain Barraud]], [[https://​aip.scitation.org/​doi/​10.1063/​1.3226856|Phase-coherent quantum transport in silicon nanowires based on Wigner transport equation: Comparison with the nonequilibrium-Green-function formalism]],​ J. Appl. Phys. **106**, 063714 (2009)
 +  * Huu-Nha Nguyen, [[Damien Querlioz]], Sylvie Galdin-Retailleau,​ Arnaud Bournel, and [[Philippe Dollfus]], [[https://​ieeexplore.ieee.org/​document/​5091161|Wigner Monte Carlo simulation of CNTFET: Comparison between semi-classical and quantum transport]],​ Proc. IWCE, 257 (2009)
 +  * [[Zhengyun Zhang]] and Marc Levoy, [[https://​ieeexplore.ieee.org/​document/​5559007|Wigner distributions and how they relate to the light field]], Proc. IEEE International Conference on Computational Photography (ICCP), 1-10 (2009)
 +  * [[Bartlomiej Spisak]], [[Maciej Woloszyn]], P. Wojcik, G.J. Morgan, [[https://​iopscience.iop.org/​article/​10.1088/​1742-6596/​193/​1/​012130|Wigner distribution function description of a multilayered nanostructure with magnetic impurities]],​ J. Phys.: Conf. Ser. **193**, 012130 (2009) ​
 +  * P. Wojcik, [[Bartlomiej Spisak]], [[Maciej Woloszyn]], J. Adamowski, [[https://​iopscience.iop.org/​article/​10.1088/​0268-1242/​24/​9/​095012|Self-consistent Wigner distribution function study of gate-voltage controlled triple-barrier resonant tunnelling diode]], Semicond. Sci. Technol. **24**, 095012 (2009) ​
 +  * [[Bartlomiej Spisak]], [[Maciej Woloszyn]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.80.035127|Nonclassical properties of electronic states of aperiodic chains in a homogeneous electric field]], Phys. Rev. B **80**, 035127 (2009) ​
 +
 +=== 2008 ===
 +  * [[Damien Querlioz]], Jerome Saint-Martin,​ Arnaud Bournel, and [[Philippe Dollfus]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.78.165306|Wigner Monte Carlo simulation of phonon-induced electron decoherence in semiconductor nanodevices]],​ Phys. Rev. B **78**, 165306 (2008)
 +  * Taj, David and [[Fausto Rossi]], [[https://​onlinelibrary.wiley.com/​doi/​abs/​10.1002/​pssc.200776527|Quantum non-locality in systems with open boundaries: From the Wigner-function formalism to non-homogeneous Markovian master equations]],​ physica status solidi (c) **5**, 66 (2008)
 +
 +=== 2007 ===
 +  * [[Clemens Heitzinger]],​ [[Christian Ringhofer]],​ [[Shaikh S. Ahmed]], and [[Dragica Vasileska]],​ [[https://​link.springer.com/​article/​10.1007/​s10825-006-0058-x|3D Monte-Carlo device simulations using an effective quantum potential including electron-electron interactions]], ​ J. Comput. Electron. **6**, 15 (2007)
 +  * Emiliano Cancellieri,​ [[Paolo Bordone]], and [[Carlo Jacoboni]], [[https://​journals.aps.org/​prb/​pdf/​10.1103/​PhysRevB.76.214301|Effect of symmetry in the many-particle Wigner function]], Phys. Rev. B **76**, 214301 (2007)
 +  * Emiliano Cancellieri,​ [[Paolo Bordone]], and [[Carlo Jacoboni]], [[http://​eprints.whiterose.ac.uk/​84429/​|Effect of the Pauli Exclusion Principle in the Many-Electron Wigner Function]] (2007)
 +  * [[Ram Bilas Pachori]] and P. Sircar, [[https://​www.sciencedirect.com/​science/​article/​pii/​S1051200406001436|A new technique to reduce cross terms in the Wigner distribution]],​ Dig. Sig. Proc. **17**, 466 (2007)
 +  * [[Hans Kosina]], [[https://​www.worldscientific.com/​doi/​abs/​10.1142/​S0129156407004667|Nanoelectronic Device Simulation Based on the Wigner Function Formalism]],​ Int. J. High Speed Electron. Sys. **17**, 475 (2007)
 +
 +=== 2006 ===
 +  * Taj, D and Genovese, L and [[Fausto Rossi]], [[https://​iopscience.iop.org/​article/​10.1209/​epl/​i2006-10047-3|Quantum-transport simulations with the Wigner-function formalism: Failure of conventional boundary-condition schemes]], Europhys. Lett. **74**, 1060 (2006)
 +  * Taj, David and Genovese, L and [[Fausto Rossi]], [[https://​onlinelibrary.wiley.com/​doi/​abs/​10.1002/​pssc.200668052|Transport in quantum devices: modelling contacts in the Wigner formalism]],​ physica status solidi (c) **3**, 2419 (2006)
 +  * [[Harold Grubin]], [[https://​www.scientific.net/​AST.52.36|Transient Wigner function studies of DMS barrier devices]], Adv. Sci. Techn. **52**, 36 (2006)
 +  * V. Sverdlov, T. Grasser, [[Hans Kosina]], and [[Siegfried Selberherr]],​ [[https://​link.springer.com/​article/​10.1007%2Fs10825-006-0041-6|Scattering and Space-Charge Effects in Wigner Monte Carlo Simulations of Single and Double Barrier Devices]], ​ J. Comp. Electron. **5**, 447 (2006)
 +  * [[Damien Querlioz]], Jerome Saint-Martin , Van-Nam Do, Arnaud Bournel, and [[Philippe Dollfus]], [[https://​ieeexplore.ieee.org/​abstract/​document/​4011939|A study of quantum transport in end-of-roadmap DG-MOSFETs using a fully self-consistent Wigner Monte Carlo approach]], IEEE T. Nanotechnol. **5**, 737 (2006)
 +  * [[Damien Querlioz]], [[Philippe Dollfus]], Van-Nam Do, Bournel, Arnaud, et al., [[https://​link.springer.com/​article/​10.1007/​s10825-006-0044-3|An improved Wigner Monte-Carlo technique for the self-consistent simulation of RTDs]], J. Comput. Electron. **5**, 443 (2006)
 +  * [[Hans Kosina]], [[http://​www.inderscience.com/​offer.php?​id=12762|Wigner function approach to nano device simulation]],​ Int. J. Comp. Sci. Eng. **2**, 100 (2006)
 +
 +
 +=== 2005 ===
 +  * Patrick Loughlin and [[Leon Cohen]], [[https://​asa.scitation.org/​doi/​10.1121/​1.2001488|A Wigner approximation method for wave propagation]],​ J. Acoust. Soc. Amer **118**, 1268 (2005)
 +  * V. Sverdlov, A. Gehring, [[Hans Kosina]], and [[Siegfried Selberherr]],​ [[https://​www.sciencedirect.com/​science/​article/​pii/​S003811010500198X?​via%3Dihub|Quantum Transport in Ultra-Scaled Double-Gate MOSFETs: A Wigner Function-Based Monte Carlo Approach]], Sol. Stat. Electron. **49**, 1510 (2005)
 +  * Genovese, Luigi and Taj, David and [[Fausto Rossi]], [[https://​arxiv.org/​abs/​cond-mat/​0506757|Quantum Non-Locality in Systems with Open Boundaries: Failure of the Wigner-Function Formalism]],​ arXiv:​cond-mat/​0506757 (2005)
 +  * Chiara Manzini and [[Luigi Barletti]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0362546X04003359|An analysis of the Wigner--Poisson problem with inflow boundary conditions]],​ Nonl. Anal. Theor. Meth. Appl. **60**, 77 (2005)
 +  * [[Lucio Demeio]], [[Paolo Bordone]], and [[Carlo Jacoboni]], [[https://​www.tandfonline.com/​doi/​abs/​10.1080/​00411450508951151|Multiband,​ non-parabolic Wigner-function approach to electron transport in semiconductors]],​ Trans. Theor Stat. Phys. **34**, 499 (2005)
 +  * A. Gehring and [[Hans Kosina]], [[https://​link.springer.com/​article/​10.1007/​s10825-005-7109-6|Wigner Function-Based Simulation of Quantum Transport in Scaled DG-MOSFETs Using a Monte Carlo Method]], J. Comp. Electron. **4**, 67 (2005)
 +  * [[Bartlomiej Spisak]], A. Paja, G.J. Morgan, [[https://​onlinelibrary.wiley.com/​doi/​abs/​10.1002/​pssb.200440024|Influence of spin–orbit interaction on the electrical conductivity of three-dimensional disordered systems]], phys. stat. sol. (b) **242**, 1460 (2005) ​
 +
 +=== 2004 ===
 +  * [[Carlo Jacoboni]] and [[Paolo Bordone]], [[https://​iopscience.iop.org/​article/​10.1088/​0034-4885/​67/​7/​R01/​meta|The Wigner-function approach to non-equilibrium electron transport]],​ Rep. Prog. Phys. **67**, 1033 (2004)
 +  * Zaccaria, Remo Proietti and [[Fausto Rossi]], [[https://​iopscience.iop.org/​article/​10.1088/​0268-1242/​19/​4/​086|Generalized Weyl--Wigner formalism for the simulation of open quantum devices: a density-matrix approach]], Semicond. Sci. Techn. **19**, S257 (2004)
 +  * [[Harold Grubin]], [[https://​www.spiedigitallibrary.org/​conference-proceedings-of-spie/​5584/​0000/​Wigner-function-studies-of-spin-transport-in-dilute-magnetic-semiconductor/​10.1117/​12.582770.short?​SSO=1|Wigner function studies of spin transport in dilute magnetic semiconductor barrier structures]],​ Proc. SPIE **5584** (2004)
 +  * [[Lucio Demeio]], [[Paolo Bordone]], and [[Carlo Jacoboni]], [[https://​iopscience.iop.org/​article/​10.1088/​0268-1242/​19/​4/​082|Numerical simulation of intervalley transitions by the Wigner-function approach]], Semicond. Sci. Techn. **19**, S244 (2004)
 +  * Rossella Brunetti, Stefano Monastra, and [[Carlo Jacoboni]], [[https://​iopscience.iop.org/​article/​10.1088/​0268-1242/​19/​4/​084|Quantum dynamics of polaron formation with the Wigner-function approach]], Semicond. Sci. Techn. **19**, S250 (2004)
 +
 +=== 2003 ===
 +  * [[Luigi Barletti]], [[https://​www.tandfonline.com/​doi/​full/​10.1081/​TT-120024764|Wigner envelope functions for electron transport in semiconductor devices]], Trans. Theor Stat. Phys. **32**, 253 (2003)
 +  * [[Luigi Barletti]], [[http://​www.bdim.eu/​item?​id=BUMI_2003_8_6B_3_693_0|A mathematical introduction to the Wigner formulation of quantum mechanics]],​ Bollettino dell'​Unione Matematica Italiana **6**, 693 (2003)
 +  * Zaccaria, Remo Proietti and Iotti, Rita C and [[Fausto Rossi]], [[https://​link.springer.com/​article/​10.1023/​B:​JCEL.0000011415.34531.b1|Microscopic Modelling of Quantum Open Systems: A Generalized Wigner-Function Approach]], J. Comput. Electron. **2**, 141 (2003)
 +  * [[Lucio Demeio]], [[Luigi Barletti]], [[Paolo Bordone]] and [[Carlo Jacoboni]], [[https://​www.tandfonline.com/​doi/​full/​10.1081/​TT-120024766|Wigner function for multiband transport in semiconductors]],​ Trans. Theor Stat. Phys. **32**, 307 (2003)
 +  * [[Paolo Bordone]], Alberto Bertoni, Rossella Brunetti, and [[Carlo Jacoboni]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0378475402002410|Monte Carlo simulation of quantum electron transport based on Wigner paths]], Math. Comput. Simul. **62**, 307 (2003)
 +  * [[Carlo Jacoboni]], Rossella Brunetti, and Stefano Monastra: "​Quantum dynamics of polaron formation with the Wigner-function approach",​ Physical Review B, Vol.68, No.12, p.125205, 2003.
 +  * [[Bartlomiej Spisak]], A. Paja, [[https://​www.worldscientific.com/​doi/​abs/​10.1142/​9789812704474_0036|New Approach to the Spin-Orbit Scattering of Electrons in Disordered Metallic Systems]], Proceedings of the 7th International School on Theoretical Physics, World Scientific, New Jersey-London-Hong Kong-Singapore 2003
 +
 +=== 2002 === 
 +  * Zaccaria, Remo Proietti and [[Fausto Rossi]], [[https://​arxiv.org/​abs/​cond-mat/​0204637|Generalized Wigner Function Formulation for Quantum Systems with Open Boundaries]],​ arXiv:​cond-mat/​0204637 (2002)
 +  * Michalopoulou,​ Zoi-Heleni and [[Leon Cohen]], [[https://​asa.scitation.org/​doi/​abs/​10.1121/​1.4778105|Wigner--Ville representations for acoustic source localization]],​ J. Acoust. Soc. Amer. **111**, 2386 (2002)
 +  * [[Lucio Demeio]], [[Luigi Barletti]], Andrea Bertoni, [[Paolo Bordone]], and [[Carlo Jacoboni]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0921452601013540|Wigner-function approach to multiband transport in semiconductors]],​ Phys. B Cond. Matt. **314**, 104 (2002)
 +  * [[Paolo Bordone]] and [[Carlo Jacoboni]], [[https://​link.springer.com/​article/​10.1023/​A:​1020715827744|Wigner Paths for Quantum Transport]],​ J. Comput. Electron. **1**, 67 (2002)
 +  * [[Paolo Bordone]], Andrea Bertoni, ​ and [[Carlo Jacoboni]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0921452601013552|Infinite barriers and classical force in the Wigner-function approach to quantum electron transport]],​ Phys. B Cond. Matt. **314**, 123 (2002)
 +  * Patrick Loughli and [[Leon Cohen]], [[https://​www.tandfonline.com/​doi/​abs/​10.1080/​0950034021000016784|Wigner distributions local properties of dispersive pulses]], J. Mod. Opt. **49**, 2645 (2002)
 +  * [[Harold Grubin]], R.C. Buggeln, [[https://​link.springer.com/​article/​10.1023/​A:​1020751308180|RTD Relaxation Oscillations,​ the Time Dependent Wigner Equation and Phase Noise]], J. Comp. Electron. **1**, 33 (2002)
 +
 +=== 2001 ===
 +  * [[Luigi Barletti]] and Paul F Zweifel, [[https://​www.tandfonline.com/​doi/​full/​10.1081/​TT-100105935|Parity-decomposition method for the stationary Wigner equation with inflow boundary conditions]],​ Trans. Theor Stat. Phys. **30**, 507 (2001)
 +  * [[Carlo Jacoboni]], Rossella Brunetti, [[Paolo Bordone]], and Andrea Bertoni, [[https://​www.worldscientific.com/​doi/​abs/​10.1142/​S0129156401000897|Quantum transport and its simulation with the Wigner-function approach]], Int. J. High Speed Electron. Sys. **11**, 387 (2001)
 +  * [[Carlo Jacoboni]], Andrea Bertoni, [[Paolo Bordone]], and Rossella Brunetti, [[https://​www.sciencedirect.com/​science/​article/​pii/​S0378475400002470|Wigner-function formulation for quantum transport in semiconductors:​ theory and Monte Carlo approach]], Math. Comput. Simul. **55**, 67 (2001)
 +
 +=== 1998 ===
 +  * Sangchul Oh, Kyoung-Wan Park, [[Mincheol Shin]], Seongjae Lee, and El-Hang Lee, [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.57.2368|Master Equation for the Wigner Function of Normal and Superconducting Single-electron Transistors]],​ Phys. Rev. B **57**, 57 (1998)
 +  * [[Harold Grubin]], [[https://​www.spiedigitallibrary.org/​conference-proceedings-of-spie/​3277/​0000/​Wigner-function-and-density-matrices-and-their-application-to-transport/​10.1117/​12.306157.short|Wigner function and density matrices and their application to transport properties of semiconductor devices]], Proc. SPIE **3277** (1998)
 +
 +=== 1993 ===
 +  * [[David K. Ferry]] and J.-R. Zhou, [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.48.7944|Form of the Quantum Potential for use in Hydrodynamic Equations for Semiconductor Device Modeling]], Phys. Rev. B **48**, 7944 (1993)
 +
 +=== 1989 ===
 +  * [[Walter Poetz]], [[https://​aip.scitation.org/​doi/​abs/​10.1063/​1.344257|Self‐consistent model of transport in quantum well tunneling structures]],​ J. Appl. Phys. **66**, 2458 (1989)
 +
 +
 +=== 1987 ===  ​
 +  * N. Kluksdahl, [[Walter Poetz]], U. Ravaioli and [[David K. Ferry]], [[https://​www.sciencedirect.com/​science/​article/​pii/​0749603687901753|Wigner function study of a double quantum barrier resonant tunnelling diode]], Superlatt. Microstruct. **3**, 41 (1987)
 +
 +=== 1985 ===
 +  * U. Ravaioli, M.A. Osman, [[Walter Poetz]], N. Kluksdahl and [[David K. Ferry]], [[https://​www.sciencedirect.com/​science/​article/​pii/​0378436385903171|Investigation of ballistic transport through resonant-tunnelling quantum wells using wigner function approach]]",​ Physica B+C **134**, 36 (1985)
 +
 +=== 1981 ===
 +  * [[Gerald J Iafrate]], [[Harold Grubin]], and [[David K. Ferry]], [[https://​jphyscol.journaldephysique.org/​articles/​jphyscol/​abs/​1981/​07/​jphyscol198142C737/​jphyscol198142C737.html|Utilization of Quantum Distribution Functions for Ultra-Submicron Device Transport]],​ J. Phys. Colloques **42**, 307 (1981)
 +
 ==== Mathematical and Theoretical Physics ====  ==== Mathematical and Theoretical Physics ==== 
 === 2019 === === 2019 ===
 +  * [[Herbert Spohn]], [[https://​link.springer.com/​article/​10.1007/​s10955-019-02320-5|Generalized Gibbs Ensembles of the Classical Toda Chain]], Journal of Statistical Physics (2019)
 +  * Marcos Saraceno and [[Alfredo Miguel Ozorio de Almeida]], [[https://​iopscience.iop.org/​article/​10.1088/​1751-8121/​aafdc2|Translations and reflections on the torus: identities for discrete Wigner functions and transforms]],​ J. Phys. A **52**, 095301 (2019)
 +  * Xiang-Guo Meng, Jian-Ming Liu, Ji-Suo Wang, and [[Hongyi Fan]], [[https://​link.springer.com/​article/​10.1140/​epjd/​e2018-90224-6|New generalized binomial theorems involving two-variable Hermite polynomials via quantum optics approach and their applications]],​ Europ. Phys. J. D **73**, 32 (2019)
 +  * [[Haiyan Jiang]], [[Tiao Lu]], and Xiangjiang Zhu, [[https://​link.springer.com/​article/​10.1007/​s11464-019-0750-3|Well-posedness of a non-local abstract Cauchy problem with a singular integral]], Front. Math. Chin. **14**, 77 (2019)
 +  * [[Franz Luef]] and Eirik Skrettingland,​ [[https://​link.springer.com/​article/​10.1007/​s00041-019-09663-3|Mixed-State Localization Operators: Cohen’s Class and Trace Class Operators]],​ J. Four. Anal. Appl. **25**, 2064 (2019)
 +
 +
 === 2018 === === 2018 ===
     * [[Leon Cohen]], [[https://​doi.org/​10.1088/​1402-4896/​aad0fc|Transformation of quasi-distributions]],​ Phys. Scr. **93**, ​ 094001 (2018)     * [[Leon Cohen]], [[https://​doi.org/​10.1088/​1402-4896/​aad0fc|Transformation of quasi-distributions]],​ Phys. Scr. **93**, ​ 094001 (2018)
 +  * Claude Bardos and [[Norbert J. Mauser]], [[https://​www.ems-ph.org/​journals/​show_abstract.php?​issn=1027-488X&​vol=9&​iss=109&​rank=5|Kinetic Equations: A French History]], EMS Newsletter (2018)
 +
 === 2017 === === 2017 ===
 +  * Jonathan S. Ben‐Benjamin,​ Moochan B. Kim, [[Wolfgang Schleich]], [[William B. Case]], and [[Leon Cohen]], [[https://​onlinelibrary.wiley.com/​doi/​full/​10.1002/​prop.201600092|Working in phase‐space with Wigner and Weyl]], Fortschr. Phys. **65**, 1600092 (2017)
 +  * S Agyo, [[Ci Lei]], and A Vourdas, [[https://​aip.scitation.org/​doi/​full/​10.1063/​1.4983917|The groupoid of bifractional transformations ]], J. Math. Phys. **58**, 052103 (2017)
 +  * [[Hans Kastrup]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.95.052111|Wigner functions for angle and orbital angular momentum: Operators and dynamics]], Phys. Rev. A **95**, 052111 (2017)
 +
 +
 === 2016 === === 2016 ===
 +  * M. Saraceno and [[Alfredo Miguel Ozorio de Almeida]], [[https://​iopscience.iop.org/​article/​10.1088/​1751-8113/​49/​14/​145302|Representation of superoperators in double phase space]], J. Phys A **49**, 145302 (2016)
 +  * Christian R Müller, Christian Peuntinger, Thomas Dirmeier, Imran Khan, Ulrich Vogl, Ch Marquardt, [[Gerd Leuchs]], Luis L Sánchez-Soto,​ Yong Siah Teo, Zdenek Hradil, Jaroslav Řeháček, [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.117.070801|Evading Vacuum Noise: Wigner Projections or Husimi Samples?]], Phys. Rev. Lett. **117**, 070801 (2016)
 +  * [[Ivan Dimov]], [[Mihail (Mixi) Nedjalkov]],​ J.M. Sellier, [[Siegfried Selberherr]],​ [[https://​link.springer.com/​chapter/​10.1007%2F978-3-319-23413-7_97|Neumann Series Analysis of the Wigner Equation Solution]], in: Progress in Industrial Mathematics,​ The European Consortium for Mathematics in Industry **22**, 701 (2016)
 +  * [[Hans Kastrup]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.94.062113|Wigner functions for the pair angle and orbital angular momentum]], Phys. Rev. A **94**, 062113 (2016)
 +
 === 2015 === === 2015 ===
 +  * E. Colomés, Z. Zhan, and [[Xavier Oriols]], [[http://​link.springer.com/​article/​10.1007/​s10825-015-0737-6|Comparing Wigner, Husimi and Bohmian distributions:​ which one is a true probability distribution in phase space?]], J. Comp. Electro. **14**, 894 (2015)
 +  * P. Evangelides,​ [[Ci Lei]], and A. Vourdas, [[https://​aip.scitation.org/​doi/​full/​10.1063/​1.4927256|Analytic representations with theta functions for systems on ℤ(d) and on 𝕊]], J. Math. Phys. **56**, 072108 (2015)
 +  * S Agyo, [[Ci Lei]], and A Vourdas, [[https://​iopscience.iop.org/​article/​10.1088/​1742-6596/​597/​1/​012007|Bi-fractional Wigner functions]],​ J. Phys.: Conf. Ser. **597**, 012007 (2015)
 +  * S Agyo, [[Ci Lei]], and A Vourdas, [[https://​www.sciencedirect.com/​science/​article/​pii/​S0375960114011633|Interpolation between phase space quantities with bifractional displacement operators]],​ Phys. Lett. A **379**, 255 (2015)
 +
 +=== 2014 ===
 +  * [[Nuno Costa Dias]], [[Maurice de Gosson]], and [[João Nuno Prata]], [[https://​www.ams.org/​journals/​proc/​2014-142-09/​S0002-9939-2014-12311-2/​S0002-9939-2014-12311-2.pdf|Maximal covariance group of Wigner transforms and pseudo-differential operators]],​ Proc. Amer. Math. Soc. **142**, 3183 (2014)
 +  * [[Ruo Li]], [[Tiao Lu]], and [[Zhangpeng Sun]], [[https://​epubs.siam.org/​doi/​abs/​10.1137/​130941754|Stationary Wigner equation with inflow boundary conditions: will a symmetric potential yield a symmetric solution?​]],​ SIAM J. Appl. Math. **74**, 885 (2014)
 +  * [[Ruo Li]], [[Tiao Lu]], and [[Zhangpeng Sun]], [[https://​arxiv.org/​abs/​1406.4213v1|Convergence of semi-discrete stationary Wigner equation with inflow boundary conditions]],​ arXiv:​1406.4213 (2014)
 +
 +=== 2013 ===
 +  * [[Alfredo Miguel Ozorio de Almeida]], R.O. Vallejos, and E. Zambrano, [[https://​iopscience.iop.org/​article/​10.1088/​1751-8113/​46/​13/​135304/​meta|Initial or final values for semiclassical evolutions in the Weyl-Wigner representation]],​ J. Phys. A **46**, 13504 (2013)
 +  * [[Nuno Costa Dias]], [[Maurice de Gosson]], and [[João Nuno Prata]], [[https://​www.worldscientific.com/​doi/​abs/​10.1142/​S0129055X13430101|Metaplectic formulation of the Wigner transform and applications]],​ Rev. Math. Phys. **25**, 1343010 (2013)
 +  * Zhenning Cai, Yuwei Fan, [[Ruo Li]], [[Tiao Lu]], and Yanli Wang, [[https://​aip.scitation.org/​doi/​full/​10.1063/​1.4748971|Quantum hydrodynamic model by moment closure of Wigner equation]], J. Math. Phys. **53**, 103503 (2012)
 +
 +=== 2012 ===
 +  * Earnshaw RA, Lei C, Li J, Mugassabi S and [[Apostol Vourdas]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0378437111008958|Large scale data analysis using the Wigner function]], Physica A **391**, 2401-2407 (2012)
 +  * [[Anton Arnold]], I. Gamba, M.P. Gualdani, S. Mischler, C. Mouhot, C. Sparber, [[https://​www.worldscientific.com/​doi/​abs/​10.1142/​S0218202512500340|The Wigner-Fokker-Planck equation: stationary states and large time behavior]], Math. Mod. Methods Appl. Sc. **22**, 1250034 (2012)
 +  * [[Nuno Costa Dias]], [[Maurice de Gosson]], [[Franz Luef]], and [[João Nuno Prata]], [[https://​link.springer.com/​article/​10.1007/​s11868-012-0054-9|Quantum Mechanics in Phase Space: The Schrodinger and the Moyal Representations]],​ J. Pseudodiff. Oper. Appl. **3**, 367 (2012)
 +  * [[Maurice de Gosson]] and Serge M. de Gosson, [[https://​www.sciencedirect.com/​science/​article/​pii/​S0375960111013326?​via%3Dihub|Weak values of a quantum observable and the cross-Wigner distribution]],​ Phys. Lett. A **376**, 293 (2012)
 +
 +=== 2011 ===
 +  * Timothy M. Coffey, [[Robert Wyatt]], and Wm. C. Schieve, [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.107.230403|Reconstruction of the Time-Dependent Wave Function Exclusively from Position Data]], Phys. Rev. Lett. **107**, 230403 (2011)
 +  * K. Ma, [[Jian-Hua Wang]], Y. Yuan, [[http://​iopscience.iop.org/​article/​10.1088/​1674-1137/​35/​1/​003|Wigner Function for the Dirac Oscillator in Spinor Space]], Chinese Physics C **35**, 11-15 (2011)
 +  * [[Nuno Costa Dias]], [[Maurice de Gosson]], [[Franz Luef]], and [[João Nuno Prata]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0021782411000912|A Pseudo-Differential Calculus on Non-Standard Symplectic Space; Spectral and Regularity Results in Modulation Spaces]], J. Math. Pur. Appl. **96**, 423 (2011)
 +  * [[Maurice de Gosson]], [[https://​link.springer.com/​article/​10.1007/​s11868-011-0023-8|A transformation property of the Wigner distribution under Hamiltonian symplectomorphisms]],​ J. Pseudo-Differ. Oper. Appl. **2**, 91 (2011)
 +
 +=== 2010 ===
 +  * R. Mack, J. P. Dahl, H. Moya-Cessa, W. T. Strunz, [[Reinhold Walser]], and [[Wolfgang Schleich]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.82.032119|Riemann ζ function from wave-packet dynamics]], Phys. Rev. A **82**, 032119 (2010)
 +  *[[Apostol Vourdas]], [[https://​link.springer.com/​article/​10.1134/​S1063778810020055|Wigner and Weyl functions for p-adic quantum mechanics]],​ Physics of atomic nuclei **73**, 237-241 (2010)
 +  * O. Brodier and [[Alfredo Miguel Ozorio de Almeida]], [[https://​www.sciencedirect.com/​science/​article/​abs/​pii/​S0375960110004007?​via%3Dihub|Markovian evolution of Gaussian states in the semiclassical limit]], Phys. Lett. A **374**, 2315 (2010)
 +  * [[Basil J. Hiley]], [[https://​link.springer.com/​article/​10.1007/​s10701-009-9320-y|On the Relationship Between the Wigner-Moyal and Bohm Approaches to Quantum Mechanics: A Step to a More General Theory?]], Found. Phys. **40**, 356 (2010)
 +  * [[Nuno Costa Dias]], [[Maurice de Gosson]], [[Franz Luef]], and [[João Nuno Prata]], [[https://​aip.scitation.org/​doi/​10.1063/​1.3436581|A Deformation Quantization Theory for Noncommutative Quantum Mechanics]],​ J. Math. Phys. **51**, 072101 (2010)
 +  * Bastos, C., [[Nuno Costa Dias]], and [[João Nuno Prata]], [[https://​link.springer.com/​article/​10.1007/​s00220-010-1109-5|Wigner Measures in Noncommutative Quantum Mechanics]],​ Comm. Math. Phys. **299**, 709 (2010)
 +
 +=== 2009 ===
 +  * [[Nuno Costa Dias]] and [[João Nuno Prata]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0034487709000081|The Narcowich-Wigner spectrum of a pure state]], Rep. Math. Phys. **63**, 43 (2009)
 +  * Agissilaos G. Athanassoulis,​ [[Norbert J. Mauser]], and Thierry Paul, [[https://​www.sciencedirect.com/​science/​article/​pii/​S0021782409000038|Coarse-scale representations and smoothed Wigner transforms]],​ J. Math. Pur. Appl. **91**, 296 (2009) ​
 +  * Remi Carles, Clotilde Fermanian Kammerer, [[Norbert J. Mauser]], and Hans Peter Stimming, [[https://​www.aimsciences.org/​journals/​displayArticles.jsp?​paperID=3858|On the time evolution of Wigner measures for Schrodinger equations]], ​ Commun. Pure Appl. Anal. **8**, 559 (2009) ​
 +
 +=== 2008 ===
 +  * [[Fabricio Toscano]], A. Kenfack, A. R. R. Carvalho, J. M. Rost, and [[Alfredo Miguel Ozorio de Almeida]],​[[https://​royalsocietypublishing.org/​doi/​abs/​10.1098/​rspa.2007.0263|Husimi-Wigner representation of chaotic eigenstates]],​ Proc. Roy. Soc. A **464**, 1503 (2008)
 +  * [[William B. Case]], [[http://​aapt.scitation.org/​doi/​10.1119/​1.2957889|Wigner functions and Weyl transforms for pedestrians]],​ Amer. J. Phys. **76**, 937 (2008)
 +  * Bastos, Catarina, Bertolami, Orfeu, [[Nuno Costa Dias]], and [[João Nuno Prata]], [[https://​aip.scitation.org/​doi/​full/​10.1063/​1.2944996|Weyl--Wigner formulation of noncommutative quantum mechanics]],​ J. Math. Phys. **49**, 072101 (2008)
 +
 +=== 2007 ===
 +  * [[Nuno Costa Dias]] and [[João Nuno Prata]], [[https://​aip.scitation.org/​doi/​full/​10.1063/​1.2409495|Features of Moyal trajectories]],​ J. Math. Phys. **48**, 012109 (2007) ​
 +  * [[Basil J. Hiley]], [[https://​www.worldscientific.com/​doi/​abs/​10.1142/​9789812771186_0017|Phase Space Description of Quantum Mechanics and Non-commutative Geometry: Wigner-Moyal and Bohm in a wider context]], in //Beyond the Quantum//, 203 (2007)
 +
 +=== 2006 ===
 +  * [[Leon Cohen]], [[https://​www.tandfonline.com/​doi/​full/​10.1080/​09500340600952051|Wigner distribution for operators at different times]], J. Mod. Opt. **53**, 2377 (2006)
 +  * [[Nuno Costa Dias]], Mikovic, A., and [[João Nuno Prata]], [[https://​aip.scitation.org/​doi/​10.1063/​1.2227259|Coherent States Expectation Values as Semiclassical Trajectories]],​ J. Math. Phys. **47**, 082101 (2006) ​
 +  * [[Nuno Costa Dias]] and [[João Nuno Prata]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0003491605001922|Comment on Infinite Walls in Deformation Quantization]],​ Ann. Phys. **321**, 495 (2006) ​
 +
 +=== 2005 ===
 +  * [[Nuno Costa Dias]] and [[João Nuno Prata]], [[https://​aip.scitation.org/​doi/​10.1063/​1.1948327|Stargenfunctions,​ General Parametrized Systems and a Causal Formulation of Phase Space Quantum Mechanics]],​ J. Math. Phys. **46**, 072107 (2005)
 +  * [[Nuno Costa Dias]] and [[João Nuno Prata]], [[https://​www.worldscientific.com/​doi/​abs/​10.1142/​S0217732305017822|Deformation quantization and Wigner functions]],​ Mod. Phys. Lett. A **20**, 1371 (2005)
 +  * [[Maurice de Gosson]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0007449704001095|Cellules quantiques symplectiques et fonctions de Husimi-Wigner]],​ Bull. Sci. Math. **129**, 211 (2005)
 +
 +=== 2004 ===
 +  * [[Leon Cohen]], [[https://​www.tandfonline.com/​doi/​abs/​10.1080/​09500340408231835|Wigner quasi-distributions for arbitrary operators]],​ J. Mod. Opt. **51**, 2761 (2004)
 +  * [[Nuno Costa Dias]] and [[João Nuno Prata]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0003491604000648|Admissible States in Quantum Phase Space]], Ann. Phys. **313**, 110 (2004)
 +  * [[Nuno Costa Dias]] and [[João Nuno Prata]], [[https://​aip.scitation.org/​doi/​10.1063/​1.1641152|Time Dependent Transformations in Deformation Quantization]],​ J. Math. Phys. **45**, 887 (2004)
 +  * [[Nuno Costa Dias]] and [[João Nuno Prata]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0003491603002690|Formal Solutions of Stargenvalue Equations]],​ Ann. Phys. **311**, 120 (2004)
 +
 +=== 2003 ===
 +  * Lorenzo Galleani and [[Leon Cohen]], [[https://​www.tandfonline.com/​doi/​abs/​10.1080/​09500340308234579|Reply to:​‘Comment on “wigner equation of motion for time-dependent potentials”’by besieris and davis]], J. Mod. Opt. **50**, 2275 (2003)
 +  * [[Hongyi Fan]], [[https://​iopscience.iop.org/​article/​10.1088/​0253-6102/​40/​4/​409|General Wigner Transforms Studied by Virtue of Weyl Ordering of the Wigner Operator]], Commun. Theor. Phys. **40**, 409 (2003)
 +  * Christof Sparber, Peter A. Markowich, and [[Norbert J. Mauser]], [[https://​content.iospress.com/​articles/​asymptotic-analysis/​asy540|Wigner Functions versus WKB-Methods in Multivalued Geometrical Optics]], Asymp. Anal. **33**, 153 (2003) ​
 +
 +
 +=== 2002 ===
 +  * [[Thierry Goudon]], [[https://​epubs.siam.org/​doi/​abs/​10.1137/​S0036142901388366|Analysis of a semidiscrete version of the Wigner equation]], SIAM J. Num. Anal. **40**, 2007 (2002)
 +  * Lorenzo Galleani and [[Leon Cohen]], [[https://​www.tandfonline.com/​doi/​abs/​10.1080/​0950034021000011518|Wigner distribution for random systems]], J. Mod. Opt. **49**, 2657 (2002)
 +  * [[Leon Cohen]] and Patrick Loughli, [[https://​www.tandfonline.com/​doi/​abs/​10.1080/​09500340110087642|Generalized Wigner distributions,​ moments and conditional correspondence rules]], J. Mod. Opt. **49**, 539 (2002)
 +  * Lorenzo Galleani and [[Leon Cohen]], [[https://​www.tandfonline.com/​doi/​abs/​10.1080/​09500340110088515|Wigner equation of motion for time-dependent potentials]],​ J. Mod. Opt. **49**, 561 (2002)
 +  * [[Anton Arnold]], J. Carrillo, E. Dhamo, [[https://​www.sciencedirect.com/​science/​article/​pii/​S0022247X0200327X|On the periodic Wigner-Poisson-Fokker-Planck system]], J. Math. Anal. Appl. **275**, 263 (2002)
 +  * Lorenzo Galleani and [[Leon Cohen]], [[https://​link.springer.com/​article/​10.1155/​S1110865702000458|Approximation of the Wigner distribution for dynamical systems governed by differential equations]],​ EURASIP J. Appl. Sig. Proc. **2002**, 67 (2002)
 +  * [[Nuno Costa Dias]] and [[João Nuno Prata]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0375960102011751|Bohmian Trajectories and Quantum Phase Space Distributions]],​ Phys. Lett. A **302**, 261 (2002)
 +  * [[Nuno Costa Dias]] and [[João Nuno Prata]], [[https://​aip.scitation.org/​doi/​abs/​10.1063/​1.1504885|Wigner functions with boundaries]],​ J. Math. Phys. **43**, 4602 (2002)
 +
 +=== 2001 ===
 +  * [[Fabricio Toscano]], Marcus A. M. de Aguiar, and [[Alfredo Miguel Ozorio de Almeida]], [[https://​journals.aps.org/​prl/​abstract/​10.1103/​PhysRevLett.86.59|Scars of the Wigner function]], Phys. Rev. Lett. **86**, 59 (2001)
 +  * [[Nuno Costa Dias]] and [[João Nuno Prata]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0375960101007472|Causal Interpretation and Quantum Phase Space]], Phys. Lett. A **291**, 355 (2001)
 +   * [[Nuno Costa Dias]] and [[João Nuno Prata]], [[https://​aip.scitation.org/​doi/​10.1063/​1.1415086|Generalized Weyl--Wigner map and Vey quantum mechanics]],​ J. Math. Phys. **42**, 5565 (2001)
 +
 +=== 2000 ===
 +  * G. Giakasa, L.K. Stergioulas,​ and [[Apostol Vourdas]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S002192909900216X|Time-frequency analysis and filtering of kinematic signals with impacts using the Wigner function: accurate estimation of the second derivative]],​ Journal Biomech. **33**, 567-574 (2000)
 +  *  [[Anton Arnold]], H. Lange, P.F. Zweifel, [[https://​aip.scitation.org/​doi/​10.1063/​1.1318732|A discrete-velocity,​ stationary Wigner equation]], J. Math. Phys. **41**, 7167 (2000)
 +
 +=== 1999 ===
 +  * S. Chountasis, [[Apostol Vourdas]], and C. Bendjaballah,​ [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.60.3467|Fractional fourier operators and generalized Wigner functions]],​ Physical Review A **60**, 3467 (1999)
 +  * S. Chountasis, L. K. Stergioulas,​ and [[Apostol Vourdas]], [[https://​www.tandfonline.com/​doi/​abs/​10.1080/​09500349908231397|Quantum filtering of noise in the Wigner function]], Journal Mod. Optics **46**, 2131-2134 (1999)
 +  * [[Jan Naudts]], [[https://​link.springer.com/​article/​10.1023/​A:​1026614130824|Off-Shell Relativistic Quantum Mechanics and Formulation of Dirac'​s Equation Using Characteristic Matrices]], Int. J. Theor. Phys. **38**, 431 (1999)
 +
 +=== 1998 ===
 +  * S. Chountasis and [[Apostol Vourdas]], [[https://​journals.aps.org/​pra/​abstract/​10.1103/​PhysRevA.58.1794|Weyl and Wigner functions in an extended phase space formalism]],​ Physical Review A **58**, 1794-1798 (1998)
 +
 +=== 1996 ===
 +  * [[Anton Arnold]], [[Christian Ringhofer]],​ [[https://​epubs.siam.org/​doi/​abs/​10.1137/​S003614299223882X?​journalCode=sjnaam|An operator splitting method for the Wigner-Poisson problem]], SIAM J. Num. Anal. **33**, 1622 (1996)
 +
 +=== 1995 ===
 +  * H.-W. Lee, [[https://​doi.org/​10.1016/​0370-1573(95)00007-4|Theory and application of the quantum phase-space distribution functions]],​ Phys. Rep. **259**, ​ 147 (1995)
 +
 +=== 1986 ===
 +  * K. Takahashi, [[https://​doi.org/​10.1143/​JPSJ.55.762|Wigner and Husimi Functions in Quantum Mechanics]],​ J. Phys. Soc. Jpn. **55**, ​ 762 (1986)
 +
 +=== 1982 ===
 +  * [[Gerald J Iafrate]], [[Harold Grubin]], and [[David K. Ferry]], [[https://​www.sciencedirect.com/​science/​article/​pii/​0375960182900974|The Wigner distribution function]], Phys. Lett. A **87**, 145 (1982)
 +
 +
 +=== 1974 ===
 +  * S. R. Groot, [[https://​cheap-library.com/​book/​23c997f932b9bc0e28708bdd792fda0a|La transformation de Weyl et la fonction de Wigner, une forme alternative de la 
 +mecanique quantique]] (Les Presses de l'​Universitié de Montréal, 1974)
 +
 ==== Quantum Information and Processing ====  ==== Quantum Information and Processing ==== 
-=== 2019 === 
 === 2018 === === 2018 ===
   * O de los Santos-Sánchez,​ [[https://​doi.org/​10.1088/​1751-8121/​aac9e4|Qubit-nonlinear-oscillator systems: ​   * O de los Santos-Sánchez,​ [[https://​doi.org/​10.1088/​1751-8121/​aac9e4|Qubit-nonlinear-oscillator systems: ​
 from the moderate-coupling limit to the ultrastrong-coupling regime]], J. Phys. A: Math. Theor. **51**, 305303 (2018) from the moderate-coupling limit to the ultrastrong-coupling regime]], J. Phys. A: Math. Theor. **51**, 305303 (2018)
 +
 === 2017 === === 2017 ===
   * Robert Raussendorf,​ Dan E. Browne, Nicolas Delfosse, Cihan Okay, and Juan Bermejo-Vega,​ [[https://​link.aps.org/​doi/​10.1103/​PhysRevA.95.052334|Contextuality and Wigner-function negativity in qubit quantum computation]],​ Phys. Rev. A **95**, 052334 (2017)   * Robert Raussendorf,​ Dan E. Browne, Nicolas Delfosse, Cihan Okay, and Juan Bermejo-Vega,​ [[https://​link.aps.org/​doi/​10.1103/​PhysRevA.95.052334|Contextuality and Wigner-function negativity in qubit quantum computation]],​ Phys. Rev. A **95**, 052334 (2017)
-=== 2016 ===+
 === 2015 === === 2015 ===
   * Nicolas Delfosse, Philippe Allard Guerin, Jacob Bian, and Robert Raussendorf,​ [[https://​link.aps.org/​doi/​10.1103/​PhysRevX.5.021003|Wigner Function Negativity and Contextuality in Quantum Computation on Rebits]], Phys. Rev. X **5**, 021003 (2015)   * Nicolas Delfosse, Philippe Allard Guerin, Jacob Bian, and Robert Raussendorf,​ [[https://​link.aps.org/​doi/​10.1103/​PhysRevX.5.021003|Wigner Function Negativity and Contextuality in Quantum Computation on Rebits]], Phys. Rev. X **5**, 021003 (2015)
 +
 ==== Numerical Methods for Wigner Equation ====  ==== Numerical Methods for Wigner Equation ==== 
 === 2019 === === 2019 ===
 +  * Zhenzhu Chen, [[Sihong Shao]], and [[Wei Cai]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0021999119304553|A high order efficient numerical method for 4-D Wigner equation of quantum double-slit interferences]],​ J. Comput. Phys. **396**, 54 (2019)
 +  * Lukas Schulz and [[Dirk Schulz]], [[https://​ieeexplore.ieee.org/​document/​8794705|Complex Absorbing Potential Formalism Accounting for Open Boundary Conditions Within the Wigner Transport Equation]], IEEE Trans. Nanotechnology **18**, 830 (2019)
 +  * [[Orazio Muscato]] and Vincenza Di Stefano, [[https://​content.sciendo.com/​view/​journals/​caim/​10/​1/​article-p20.xml|Wigner Monte Carlo simulation without discretization error of the tunneling rectangular barrier]], Commun. Appl. Ind. Math. **10**, 20 (2019)
 +  * [[Orazio Muscato]] and Wolfgang Wagner, [[https://​www.aimsciences.org/​article/​doi/​10.3934/​krm.2019003|A stochastic algorithm without time discretization error for the Wigner equation]], Kin. Rel. Mod. **12**, 59 (2019)
   * Yunfeng Xiong and [[Sihong Shao]], [[http://​www.global-sci.com/​intro/​article_detail/​cicp/​12832.html|The Wigner Branching Random Walk: Efficient Implementation and Performance Evaluation]],​ Commun. Comput. Phys **25**, 871 (2019)   * Yunfeng Xiong and [[Sihong Shao]], [[http://​www.global-sci.com/​intro/​article_detail/​cicp/​12832.html|The Wigner Branching Random Walk: Efficient Implementation and Performance Evaluation]],​ Commun. Comput. Phys **25**, 871 (2019)
   * [[Sihong Shao]] and Yunfeng Xiong, [[http://​global-sci.com/​intro/​article_detail/​nmtma/​12690.html|A branching ​   * [[Sihong Shao]] and Yunfeng Xiong, [[http://​global-sci.com/​intro/​article_detail/​nmtma/​12690.html|A branching ​
 random walk method for many-body Wigner quantum dynamics]], Numer. Math. Theor. Meth. Appl. **12**, 21 (2019) random walk method for many-body Wigner quantum dynamics]], Numer. Math. Theor. Meth. Appl. **12**, 21 (2019)
 +  * Zhenzhu Chen, Yunfeng Xiong, and [[Sihong Shao]], [[https://​link.springer.com/​article/​10.1007/​s10915-018-0853-0|Numerical Methods for the Wigner Equation with Unbounded Potential]],​ J. Sci. Comput. **79**, 345 (2019)
 +  * M. Benam, [[Mihail (Mixi) Nedjalkov]],​ [[Siegfried Selberherr]],​ [[https://​link.springer.com/​chapter/​10.1007%2F978-3-030-10692-8_29|A Wigner Potential Decomposition in the Signed-Particle Monte Carlo Approach]], in: Numerical Methods and Applications,​ Lecture Notes in Computer Science **11189**, 263 (2019)
 +
 +
 === 2018 === === 2018 ===
   * A S Larkin, V S Filinov and V E Fortov [[https://​doi.org/​10.1088/​1751-8121/​aa98d0|Peculiarities of the momentum distribution functions of strongly correlated charged fermions]], J. Phys. A: Math. Theor. **51**, 035002 (2018)   * A S Larkin, V S Filinov and V E Fortov [[https://​doi.org/​10.1088/​1751-8121/​aa98d0|Peculiarities of the momentum distribution functions of strongly correlated charged fermions]], J. Phys. A: Math. Theor. **51**, 035002 (2018)
-  * Zhenzhu Chen, Yunfeng Xiong, ​and [[Sihong Shao]], [[https://doi.org/10.1007/s10915-018-0853-0|Numerical ​methods for the Wigner equation with unbounded potential]], J Sci Comput ​** **,(2018)+  * Lukas Schulz ​and [[Dirk Schulz]], [[https://ieeexplore.ieee.org/abstract/document/​8464085|Numerical ​Analysis of the Transient Behavior of the Non-Equilibrium Quantum Liouville Equation]], IEEE Trans. Nanotechnology ​**17**, 1197(2018) 
 === 2017 === === 2017 ===
 +  *[[Maarten Van de Put]], Bart Soree, and [[Wim Magnus]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S002199911730640X|Efficient solution of the Wigner–Liouville equation using a spectral decomposition of the force field]], J. Comp. Phys. **350**, 314 (2017)
 +  * [[Orazio Muscato]] and Vincenza Di Stefano, [[https://​iopscience.iop.org/​article/​10.1088/​1742-6596/​906/​1/​012011/​meta|Efficient Monte Carlo-based algorithms for the Wigner transport equation]], J. Phys. Conf. Ser. **906**, 012011 (2017)
   * Andrea Thomann and Alfio Borzì, [[https://​doi.org/​10.1002/​num.22072|Stability and accuracy of a pseudospectral scheme for the Wigner function equation]], Numer. Meth. Part. Differ. Equat. **33**, 62 (2017)   * Andrea Thomann and Alfio Borzì, [[https://​doi.org/​10.1002/​num.22072|Stability and accuracy of a pseudospectral scheme for the Wigner function equation]], Numer. Meth. Part. Differ. Equat. **33**, 62 (2017)
 +  * Khuram Shahzad Khalid, Lukas Schulz and [[Dirk Schulz]], [[https://​ieeexplore.ieee.org/​abstract/​document/​8023854|Self-Energy Concept for the Numerical Solution of the Liouville-von Neumann Equation]], IEEE Trans. Nanotechnology **16**, 1053 (2017)
 +
 === 2016 === === 2016 ===
   * Yunfeng Xiong, Zhenzhu Chen, and [[Sihong Shao]], [[https://​doi.org/​10.1137/​15M1051373|An advective-spectral-mixed method for time-dependent many-body Wigner simulations]],​ SIAM J. Sci. Comput **38**, B491 (2016)   * Yunfeng Xiong, Zhenzhu Chen, and [[Sihong Shao]], [[https://​doi.org/​10.1137/​15M1051373|An advective-spectral-mixed method for time-dependent many-body Wigner simulations]],​ SIAM J. Sci. Comput **38**, B491 (2016)
 +  * [[Orazio Muscato]] and Wolfgang Wagner, [[https://​epubs.siam.org/​doi/​10.1137/​16M105798X|A Class of Stochastic Algorithms for the Wigner Equation]], SIAM J. Sci. Comp. **38**, A1483 (2016)
 +  * Lukas Schulz and [[Dirk Schulz]], [[https://​ieeexplore.ieee.org/​document/​7501465|Application of a slowly varying Envelope Function onto the Analysis of the Wigner Transport Equation]], IEEE Trans. Nanotechnology **15**, 801 (2016)
 +  * [[Dirk Schulz]] and Azhar Mahmood, [[https://​ieeexplore.ieee.org/​document/​7339425|Approximation of a Phase Space Operator for the Numerical Solution of the Wigner Equation]], IEEE J. Quantum Electron. **52**, ​ 8700109 (2016)
 +
 === 2015 === === 2015 ===
   * [[Sihong Shao]] and Jean Michel Sellier, [[https://​doi.org/​10.1016/​j.jcp.2015.08.002|Comparison of deterministic and stochastic methods for time-dependent Wigner simulations]],​ J. Comput. Phys. **300**, 167 (2015)   * [[Sihong Shao]] and Jean Michel Sellier, [[https://​doi.org/​10.1016/​j.jcp.2015.08.002|Comparison of deterministic and stochastic methods for time-dependent Wigner simulations]],​ J. Comput. Phys. **300**, 167 (2015)
-==== Engineering ​(AcousticsElectronicsSeismologySignalsetc.) ====  +  * [[Christian B. Mendl]], [[https://​www.worldscientific.com/​doi/​abs/​10.1142/​S0129183115501132|Matrix-valued quantum lattice Boltzmann method]], Int. J Mod. Phys. C **26**, 1550113 (2015) 
-=== 2019 === +  * Martin L. R. Fürst, Markus Kotulla, [[Christian B. Mendl]], and [[Herbert Spohn]], [[https://​iopscience.iop.org/​article/​10.1088/​1751-8113/​48/​9/​095204/​meta|Quantum Boltzmann equation for spin-dependent reactions in the kinetic regime]], J. Phys. A: Math. Theo. **48**, 095204 (2015) 
-=== 2018 === +  * [[Josef Weinbub]], [[Paul Ellinghaus]],​ and [[Siegfried Selberherr]],​ [[https://​link.springer.com/​chapter/​10.1007%2F978-3-319-26520-9_34|Parallelization of the Two-Dimensional Wigner Monte Carlo Method]], in: Large-Scale Scientific Computing, Lecture Notes in Computer Science **9374**, 309 (2015) 
-  * R.RSharma ​and R.BPachori, [[https://doi.org/10.1007/s00034-018-0846-0|Improved eigenvalue decomposition-based approach for reducing cross-terms in Wigner-Ville distribution]], ​Circuits Syst Signal Process ​**37**, 3330 (2018+  * [[Josef Weinbub]], [[Paul Ellinghaus]],​ [[Mihail (Mixi) Nedjalkov]],​ [[https://​link.springer.com/​article/​10.1007%2Fs10825-015-0730-0|Domain Decomposition Strategies for the Two-Dimensional Wigner Monte Carlo Method]], J. Comp. Electron. **14**, 922 (2015) 
-=== 2017 === +  * [[Paul Ellinghaus]],​ [[Josef Weinbub]], [[Mihail (Mixi) Nedjalkov]],​ [[Siegfried Selberherr]],​ and [[Ivan Dimov]], [[https://​link.springer.com/​article/​10.1007%2Fs10825-014-0635-3|Distributed-Memory Parallelization of the Wigner Monte Carlo Method Using Spatial Domain Decomposition]],​ J. Comp. Electron. **14**, 151 (2015) 
-=== 2016 === +  * J.M. Sellier, [[Mihail (Mixi) Nedjalkov]],​ [[Ivan Dimov]], and [[Siegfried Selberherr]],​ [[https://​www.sciencedirect.com/​science/​article/​abs/​pii/​S0378475414001530?​via%3Dihub|A Comparison of Approaches for the Solution of the Wigner Equation]], Math. Comp. Sim. **107**, 108 (2015) 
-  * R.BPachori and A. Nishad, [[https://doi.org/10.1016/j.sigpro.2015.07.026|Cross-terms reduction ​in Wigner-Ville distribution using tunable-Q wavelet transform]], Signal Process ​**120**, 288 (2016+  * [[Ivan Dimov]], [[Mihail (Mixi) Nedjalkov]],​ J.M. Sellier, and [[Siegfried Selberherr]],​ [[https://​link.springer.com/​article/​10.1007%2Fs10825-015-0720-2|Boundary Conditions and the Wigner Equation Solution]], J. Comp. Electron. **14**, 859 (2015) 
-=== 2015 ===+  * [[Paul Ellinghaus]],​ [[Mihail (Mixi) Nedjalkov]],​ and [[Siegfried Selberherr]],​ [[https://​link.springer.com/​chapter/​10.1007%2F978-3-319-15585-2_3|Optimized Particle Regeneration Scheme for the Wigner Monte Carlo Method]], in: Numerical Methods and Applications,​ Lecture Notes in Computer Science **8962**, 27 (2015) 
 +  * [[Johann Cervenka]], [[Paul Ellinghaus]],​ [[Mihail (Mixi) Nedjalkov]],​ [[https://​link.springer.com/​chapter/​10.1007%2F978-3-319-15585-2_17|Deterministic Solution of the Discrete Wigner Equation]], in: Numerical Methods and Applications,​ Lecture Notes in Computer Science **8962**, 149 (2015 
 +  * [[Johann Cervenka]], [[Paul Ellinghaus]],​ [[Mihail (Mixi) Nedjalkov]],​ Erasmus Langer, [[https://​link.springer.com/​chapter/​10.1007%2F978-3-319-26520-9_29|Optimization of the Deterministic Solution of the Discrete Wigner Equation]], in: large Scale Scientific Computing, Lecture Notes in Computer Science **9374**, 269 (2015) 
 +  * [[Antonius Dorda]] and [[Ferdinand Schürrer]],​ [[https://​www.sciencedirect.com/​science/​article/​pii/​S0021999114008432?​via%3Dihub|A WENO-solver combined with adaptive momentum discretization for the Wigner transport equation and its application to resonant tunneling diodes]], J. Comp. Phys. **284**, 95 (2015) 
 +  * [[Maarten Van de Put]], [[Wim Magnus]], and Bart Soree, [[http://​meetings.aps.org/​Meeting/​MAR15/​Event/​238491|A spectral force based version of the Wigner-Liouville equation]], Bull. Amer. Phys. Soc. **60** (2015) 
 + 
 +=== 2014 === 
 +  * [[Haiyan Jiang]], Tiao Lu, and [[Wei Cai]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0021999113007572|A device adaptive inflow boundary condition for Wigner equations of quantum transport]],​ J. Comput. Phys. **258**, 773 (2014) 
 +  * J.M. Sellier[[Mihail (Mixi) Nedjalkov]][[Ivan Dimov]]and [[Siegfried Selberherr]][[https://​link.springer.com/​chapter/​10.1007%2F978-3-662-43880-0_20|The Role of Annihilation in a Wigner Monte Carlo Approach]], in: Large-Scale Scientific Computing, Lecture Notes in Computer Science **8353**, 186 (2014) 
 +  * J.M. Sellier, [[Mihail (Mixi) Nedjalkov]],​ [[Ivan Dimov]], and [[Siegfried Selberherr]],​ [[https://​www.degruyter.com/​view/​j/​mcma.2014.20.issue-1/​mcma-2013-0018/​mcma-2013-0018.xml|A Benchmark Study of the Wigner Monte Carlo Method]], Mon. Carl. Meth. Appl. **20**, 43 (2014) 
 +  * J.M. Sellier and [[Ivan Dimov]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0021999114002526|A Wigner Monte Carlo approach to density functional theory]], J. Comp. Phys. **270**, 265 (2014) 
 +  * [[Maarten Van de Put]], Bart Soree, and [[Wim Magnus]], [[http://​meetings.aps.org/​Meeting/​MAR14/​Session/​S45.7|An envelope function expansion of the Wigner transport equation]], Bull. Amer. Phys. Soc. **59** (2014) 
 + 
 +=== 2013 === 
 +  * [[Mihail (Mixi) Nedjalkov]],​ P. Schwaha, [[Siegfried Selberherr]],​ J.M. Sellier, and [[Dragica Vasileska]],​ [[https://​aip.scitation.org/​doi/​10.1063/​1.4802931|Wigner Quasi-Particle Attributes - An Asymptotic Perspective]],​ Appl. Phys. Lett. **102**, 163113 (2013) 
 +  * P. Schwaha, [[Damien Querlioz]], [[Philippe Dollfus]], J. Saint-Martin,​ [[Mihail (Mixi) Nedjalkov]],​ and [[Siegfried Selberherr]],​ [[https://​link.springer.com/​article/​10.1007%2Fs10825-013-0480-9|Decoherence Effects in the Wigner Function Formalism]],​ J. Comput. Electron. **12**, 388 (2013) 
 +  * Dries Sels, Fons Brosens, and [[Wim Magnus]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0378437112008412|Wigner distribution functions for complex dynamical systems: A path integral approach]], Phys. A: Statis. Mech. Appl. **392**, 326 (2013) 
 + 
 +=== 2012 === 
 +  * [[Mihail (Mixi) Nedjalkov]],​ [[Siegfried Selberherr]],​ [[David K. Ferry]], [[Dragica Vasileska]],​ [[Philippe Dollfus]], [[Damien Querlioz]], [[Ivan Dimov]], and P. Schwaha, [[https://​www.sciencedirect.com/​science/​article/​pii/​S0003491612001558?​via%3Dihub|Physical Scales in the Wigner-Boltzmann Equation]], Ann. Phys. **328**, 220 (2012) 
 +  * Earnshaw R.A., [[Ci Lei]], Li J., Mugassabi S. and Vourdas A., [[https://​www.sciencedirect.com/​science/​article/​pii/​S0378437111008958|Large-scale data analysis using the Wigner function]], ​ Phys. A: Statis. Mech. Appl. **391**, 2401 (2012) 
 +  * Dries Sels, Fons Brosens, and [[Wim Magnus]], [[https://​www.sciencedirect.com/​science/​article/​abs/​pii/​S037596011200045X|On the path integral representation of the Wigner function and the Barker--Murray ansatz]], Phys. Lett. A **376**, 809 (2012) 
 + 
 +=== 2011 === 
 +  * [[Sihong Shao]], Tiao Lu, and [[Wei Cai]], [[https://​www.cambridge.org/​core/​journals/​communications-in-computational-physics/​article/​adaptive-conservative-cell-average-spectral-element-methods-for-transient-wigner-equation-in-quantum-transport/​71FE2A189AAB8391E03EA9D1A6F06923|Adaptive conservative cell average spectral element methods for transient Wigner equation in quantum transport]],​ Commun. Comput. Phys **9**, 711 (2011) 
 +  * [[Haiyan Jiang]], [[Wei Cai]], ​and Raphael Tsu, [[https://​www.sciencedirect.com/​science/​article/​pii/​S0021999110006662|Accuracy of the Frensley inflow boundary condition for Wigner equations in simulating resonant tunneling diodes]], J. Comput. Phys. **230**, 2031 (2011) 
 + 
 +=== 2010 === 
 +  * [[Haiyan Jiang]] and [[Wei Cai]], [[https://www.sciencedirect.com/​science/​article/​pii/​S0021999110000811|Effect of boundary treatments on quantum transport current in the Green’s function and Wigner distribution methods for a nano-scale DG-MOSFET]],​ J. Comput. Phys. **229**, 4461 (2010) 
 +  * [[Damien Querlioz]], Jerome Saint-Martin,​ and [[Philippe Dollfus]], [[https://​link.springer.com/​article/10.1007/s10825-010-0319-6|Implementation of the Wigner-Boltzmann transport equation within particle Monte Carlo simulation]],​ J. Comput. Electron. **9**, 224 (2010) 
 + 
 +=== 2009 === 
 + 
 +  * [[Damien Querlioz]], Huu-Nha Nguyen, Jerome Saint-Martin,​ Arnaud Bournel, Sylvie Galdin-Retailleau,​ and [[Philippe Dollfus]], [[https://​link.springer.com/​article/​10.1007/​s10825-009-0281-3|Wigner-Boltzmann Monte Carlo approach to nanodevice simulation: from quantum to semiclassical transport]],​ J. Comput. Electron. **8**, 324 (2009) 
 +  * Fons Brosens and [[Wim Magnus]], [[https://​onlinelibrary.wiley.com/​doi/​abs/​10.1002/​pssb.200844424|Carrier transport in nanodevices:​ revisiting the Boltzmann and Wigner ​distribution ​functions]], Phys. Stat. Sol. (b) **246**, 1656 (2009) 
 +  * Fons Brosens and [[Wim Magnus]], [[https://​onlinelibrary.wiley.com/​doi/​abs/​10.1002/​pssb.200844424|Carrier transport in nanodevices:​ revisiting the Boltzmann and Wigner distribution functions]],​ Phys. Stat. Sol. (b) **246**, 1656 (2009) 
 + 
 +=== 2008 === 
 + 
 +  * [[Kyoung-Youm Kim]], [[https://​iopscience.iop.org/​article/​10.1143/​JJAP.47.358|Nonuniform mesh application to discrete Wigner transport equation]], Jap. J. Appl. Phys. **47**, 358 (2008) 
 + 
 +=== 2007 === 
 +  * [[Kyoung-Youm Kim]], [[https://​aip.scitation.org/​doi/​full/​10.1063/​1.2818363?​showFTTab=true&​containerItemId=content%2Faip%2Fjournal%2Fjap|discrete formulation of the Wigner transport equation]], JAppl. Phys. **102**, 113705 (2007) 
 + 
 +=== 2004 === 
 +  * [[Hans Kosina]], [[Mihail (Mixi) Nedjalkov]],​ and [[Siegfried Selberherr]], [[https://www.degruyter.com/view/​j/​mcma.2004.10.issue-3-4/​mcma.2004.10.3-4.359/​mcma.2004.10.3-4.359.xml|Solution of the Space-dependent Wigner Equation Using a Particle Model]], Mon. Carl. Meth. Appl. **10**, 359 (2004) 
 +  * [[Mihail (Mixi) Nedjalkov]],​ E. Atanassov, [[Hans Kosina]], and [[Siegfried Selberherr]],​ [[https://​www.degruyter.com/​view/j/mcma.2004.10.issue-3-4/​mcma.2004.10.3-4.461/​mcma.2004.10.3-4.461.xml|Operator-Split Method for Variance Reduction ​in Stochastic Solutions of the Wigner Equation]], Mon. Carl. Meth. Appl. **10**, 461 (2004) 
 +  * [[Mihail (Mixi) Nedjalkov]],​ [[Hans Kosina]], [[Siegfried Selberherr]],​ [[Christian Ringhofer]],​ and [[David K. Ferry]], [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.70.115319|Unified Particle Approach to Wigner-Boltzmann Transport in Small Semiconductor Devices]], Phys. Rev. B **70**, 115319 (2004) 
 +  * [[Mihail (Mixi) Nedjalkov]],​ [[Hans Kosina]], E. Ungersboeck,​ and [[Siegfried Selberherr]],​ [[https://​iopscience.iop.org/​article/​10.1088/​0268-1242/​19/​4/​076|A Quasi-Particle Model of the Electron-Wigner Potential Interaction]], Semicon. Sci. Techn. ​**19**, 226 (2004) 
 + 
 +=== 2003 === 
 +  * [[Christoph Jungemann]] and Bernd Meinerzhagen,​ [[https://​www.springer.com/​gp/​book/​9783211013618|Hierarchical Device Simulation]],​ (Springer, 2003) 
 +  * [[Mihail (Mixi) Nedjalkov]],​ [[Hans Kosina]], and [[Siegfried Selberherr]],​ [[https://​www.sciencedirect.com/​science/​article/​abs/​pii/​S0026269203000697?​via%3Dihub|Stochastic Interpretation of the Wigner Transport in Nanostructures]],​ Microelectron. J. **34**, 443 (2003) 
 + 
 +=== 2002 === 
 +  * [[Mihail (Mixi) Nedjalkov]],​ [[Hans Kosina]], [[Robert Kosik]], and [[Siegfried Selberherr]],​ [[https://​link.springer.com/​article/​10.1023%2FA%3A1020799224110|Space Dependent Wigner Equation Including Phonon Interaction]],​ J. Comput. Electron. **1**, 27 (2002) 
 +  * [[Mihail (Mixi) Nedjalkov]],​ [[Hans Kosina]], [[Robert Kosik]], and [[Siegfried Selberherr]],​ [[https://​www.sciencedirect.com/​science/​article/​abs/​pii/​S0167931702006251?​via%3Dihub|A Wigner Equation with Quantum Electron-Phonon Interaction]],​ Microelectron. Engin. **63**, 199 (2002) 
 +  * L. Shifren and [[David K. Ferry]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0921452601013928?​via%3Dihub|Wigner Function Quantum Monte Carlo]], Phys. B Cond. Matt. **314**, 72 (2002)
  
-===== Miscellaneous =====+=== 2001 === 
 +  * L. Shifren and [[David K. Ferry]], [[https://​www.sciencedirect.com/​science/​article/​pii/​S0375960101003449?​via%3Dihub|Particle Monte Carlo Simulation of Wigner Function Tunneling]],​ Phys. Lett. A **285**, 217 (2001) 
 +  * [[Kyoung-Youm Kim]] and Byoungho Lee, [[https://​journals.aps.org/​prb/​abstract/​10.1103/​PhysRevB.64.115304|Wigner-function formulation in anisotropic semiconductor quantum wells]], Phys. Rev. B **64**, 115304 (2001)
  
publications.txt · Last modified: 2020/03/07 12:04 by weinbub