Zhen Tao
Yale University
23 Papers
16 Citations
Zhen Tao is an academic researcher from Yale University. The author has contributed to research in topics: Density functional theory & Proton. The author has an hindex of 7, co-authored 12 publications.
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Papers
Software for the frontiers of quantum chemistry: An overview of developments in the Q-Chem 5 package
Evgeny Epifanovsky,Andrew T.B. Gilbert,Andrew T.B. Gilbert,Xintian Feng,Xintian Feng,Joonho Lee,Yuezhi Mao,Narbe Mardirossian,Narbe Mardirossian,Pavel Pokhilko,Alec F. White,Marc P. Coons,Adrian L. Dempwolff,Zhengting Gan,Diptarka Hait,Paul R. Horn,Leif D. Jacobson,Ilya Kaliman,Jörg Kussmann,Adrian W. Lange,Ka Un Lao,Daniel S. Levine,Jie Liu,Jie Liu,Simon C. McKenzie,Adrian F. Morrison,Kaushik D. Nanda,Felix Plasser,Felix Plasser,Dirk R. Rehn,Marta L. Vidal,Zhi-Qiang You,Zhi-Qiang You,Ying Zhu,Bushra Alam,Benjamin J. Albrecht,Abdulrahman Aldossary,Ethan Alguire,J. Andersen,Vishikh Athavale,Dennis Barton,Khadiza Begam,Andrew Behn,Nicole Bellonzi,Yves A. Bernard,Eric J. Berquist,Hugh G. A. Burton,Abel Carreras,Kevin Carter-Fenk,Romit Chakraborty,Romit Chakraborty,Alan D. Chien,Kristina D. Closser,Vale Cofer-Shabica,Saswata Dasgupta,Marc de Wergifosse,Jia Deng,Michael Diedenhofen,Hainam Do,Sebastian Ehlert,Po Tung Fang,Shervin Fatehi,Shervin Fatehi,Shervin Fatehi,Qingguo Feng,Triet Friedhoff,James R. Gayvert,Qinghui Ge,Gergely Gidofalvi,Matthew Goldey,Joseph Gomes,Cristina E. González-Espinoza,Sahil Gulania,Anastasia O. Gunina,Magnus W. D. Hanson-Heine,Phillip H.P. Harbach,Andreas W. Hauser,Michael F. Herbst,Michael F. Herbst,Mario Hernández Vera,Manuel Hodecker,Zachary C. Holden,Shannon E. Houck,Xunkun Huang,Kerwin Hui,Bang C. Huynh,Maxim V. Ivanov,Ádám Jász,Hyunjun Ji,Hanjie Jiang,Benjamin Kaduk,Sven Kähler,Kirill Khistyaev,Jae-Hoon Kim,Gergely Kis,Phil Klunzinger,Zsuzsanna Koczor-Benda,Joong Hoon Koh,Dimitri Kosenkov,Laura Koulias,Tim Kowalczyk,Tim Kowalczyk,Caroline M. Krauter,Karl Y Kue,Alexander A. Kunitsa,Thomas Kus,István Ladjánszki,Arie Landau,Keith V. Lawler,Daniel Lefrancois,Susi Lehtola,Susi Lehtola,Run R. Li,Yi-Pei Li,Jiashu Liang,Marcus Liebenthal,Hung Hsuan Lin,You Sheng Lin,Fenglai Liu,Kuan-Yu Liu,Matthias Loipersberger,Arne Luenser,Aaditya Manjanath,Prashant Uday Manohar,Erum Mansoor,Sam F. Manzer,Shan Ping Mao,Aleksandr V. Marenich,Thomas Markovich,Stephen E. Mason,Simon A. Maurer,Peter F. McLaughlin,Maximilian F. S. J. Menger,Jan-Michael Mewes,Stefanie A. Mewes,Pierpaolo Morgante,J. Wayne Mullinax,Katherine J. Oosterbaan,Katherine J. Oosterbaan,Garrette Paran,Garrette Paran,Alexander C. Paul,Suranjan K. Paul,Fabijan Pavošević,Zheng Pei,Stefan Prager,Emil Proynov,Ádám Rák,Eloy Ramos-Cordoba,Bhaskar Rana,Alan E. Rask,Adam Rettig,Ryan M. Richard,Fazle Rob,Elliot Rossomme,Tarek Scheele,Maximilian Scheurer,Matthias Schneider,Nickolai Sergueev,Shaama Mallikarjun Sharada,Wojciech Skomorowski,David W. Small,Christopher J. Stein,Yu-Chuan Su,Eric J. Sundstrom,Zhen Tao,Jonathan Thirman,Gábor János Tornai,Takashi Tsuchimochi,Norm M. Tubman,Srimukh Prasad Veccham,Oleg A. Vydrov,Jan Wenzel,Jon Witte,Atsushi Yamada,Kun Yao,Sina Yeganeh,Shane R. Yost,Alexander Zech,Igor Ying Zhang,Xing Zhang,Yu Zhang,Dmitry Zuev,Alán Aspuru-Guzik,Alexis T. Bell,Nicholas A. Besley,Ksenia B. Bravaya,Bernard R. Brooks,David Casanova,Jeng-Da Chai,Sonia Coriani,Christopher J. Cramer,György Cserey,A. Eugene DePrince,Robert A. DiStasio,Andreas Dreuw,Barry D. Dunietz,Thomas R. Furlani,William A. Goddard,Sharon Hammes-Schiffer,Teresa Head-Gordon,Warren J. Hehre,Chao-Ping Hsu,Chao-Ping Hsu,Thomas-C. Jagau,Thomas-C. Jagau,Yousung Jung,Andreas Klamt,Jing Kong,Daniel S. Lambrecht,WanZhen Liang,WanZhen Liang,Nicholas J. Mayhall,C. William McCurdy,Jeffrey B. Neaton,Christian Ochsenfeld,John Parkhill,Roberto Peverati,Vitaly A. Rassolov,Yihan Shao,Lyudmila V. Slipchenko,Tim Stauch,Tim Stauch,Ryan P. Steele,Joseph E. Subotnik,Alex J. W. Thom,Alexandre Tkatchenko,Donald G. Truhlar,Troy Van Voorhis,Tomasz Adam Wesolowski,K. Birgitta Whaley,H. Lee Woodcock,Paul M. Zimmerman,Shirin Faraji,Peter Gill,Peter Gill,Martin Head-Gordon,John M. Herbert,Anna I. Krylov +238 more
TL;DR: The Q-Chem quantum chemistry program package as discussed by the authors provides a suite of tools for modeling core-level spectroscopy, methods for describing metastable resonances, and methods for computing vibronic spectra, the nuclear-electronic orbital method, and several different energy decomposition analysis techniques.
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Possible Dirac quantum spin liquid in the kagome quantum antiferromagnet <mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"><mml:mrow><mml:msub><mml:mi>YCu</mml:mi><mml:mn>3</mml:mn></mml:msub><mml:msub><mml:mrow><mml:mo>(</mml:mo><mml:mi>OH</mml:mi><mml:mo>)</mml:mo></mml:mrow><mml:mn>6</mml
Zhe Zeng,Xiaoyan Ma,Si Wu,Hai-Feng Li,Zhen Tao,Xingye Lu,Xiao-Hui Chen,Jin-Xiao Mi,Shicong Song,Guanghan Cao,G. Che,Kuo Li,Gang Li,Huiqian Luo,Z. Y. Deng,Shiliang Li +15 more
TL;DR: In this article , the magnetic properties of YCu$_3$(OH)$_6$Br$_2$[Br$_{1-x}$(oh)$(X)$[X$ = 0.33], where Cu$^{2+}$ ions form two-dimensional kagome layers, were studied.
Direct Dynamics with Nuclear-Electronic Orbital Density Functional Theory.
TL;DR: In this paper, the authors describe how various nuclear-electronic orbital (NEO) methods can be used for direct dynamics simulations on electron-proton vibronic surfaces, where the transferring proton(s) and all electrons are treated quantum mechanically.
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Proton-coupled energy transfer in molecular triads
Belinda Pettersson Rimgard,Zhen Tao,Giovanny A. Parada,Laura F Cotter,Sharon Hammes-Schiffer,James M. Mayer,Leif Hammarström +6 more
TL;DR: In this article , a photochemical mechanism of proton-coupled energy transfer (PCEnT) was discovered and theoretically analyzed in molecular triads, which is a nonadiabatic singlet-singlet energy transfer coupled to proton tunneling.
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Analytical Gradients for Nuclear-Electronic Orbital Time-Dependent Density Functional Theory: Excited-State Geometry Optimizations and Adiabatic Excitation Energies.
TL;DR: In this article, the authors derived and implemented the analytical gradients for the nuclear-electronic orbital (NEO) method and the associated Tamm-Dancoff approximation (nEO-TDA) for a set of nine small molecules with all protons quantized, exhibiting slight improvement over the conventional electronic approach.
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