L
Leeor Kronik
Researcher at Weizmann Institute of Science
Publications - 359
Citations - 24947
Leeor Kronik is an academic researcher from Weizmann Institute of Science. The author has contributed to research in topics: Density functional theory & Hybrid functional. The author has an hindex of 75, co-authored 320 publications receiving 21686 citations. Previous affiliations of Leeor Kronik include University of Wisconsin-Madison & Tel Aviv University.
Papers
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Surface photovoltage phenomena: theory, experiment, and applications
Leeor Kronik,Yoram Shapira +1 more
TL;DR: The theoretical concepts, experimental tools, and applications of surface photovoltage (SPV) techniques are reviewed in detail in detail as discussed by the authors, where the theoretical discussion is divided into two sections: electrical properties of semiconductor surfaces and the second discusses SPV phenomena.
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Hybrid organic—inorganic perovskites: low-cost semiconductors with intriguing charge-transport properties
TL;DR: In this paper, the authors summarize what is known and unknown about charge transport in HOIPs, with particular emphasis on their advantages as photovoltaic materials and highlight the fundamental questions that need to be addressed regarding the charge-transport properties of these materials.
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Orbital-dependent density functionals: Theory and applications
Stephan Kümmel,Leeor Kronik +1 more
TL;DR: In this article, the authors provide a perspective on the use of orbital-dependent functionals, which is currently considered one of the most promising avenues in modern density-functional theory.
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Reliable prediction of charge transfer excitations in molecular complexes using time-dependent density functional theory.
TL;DR: It is shown how charge transfer excitations at molecular complexes can be calculated quantitatively using time-dependent density functional theory, paving the way to systematic nonempirical quantitative studies of charge-transfer excitations in real systems.
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Excitation Gaps of Finite-Sized Systems from Optimally Tuned Range-Separated Hybrid Functionals.
TL;DR: A new approach to density functional theory that mimics successfully, to the best of the authors' knowledge for the first time, the quasi-particle picture of many-body theory and produces the correct optical gap for the difficult case of charge-transfer and charge- transfer-like scenarios, where conventional functionals are known to fail.