Z
Zhenyu Guo
Researcher at Soochow University (Suzhou)
Publications - 18
Citations - 471
Zhenyu Guo is an academic researcher from Soochow University (Suzhou). The author has contributed to research in topics: Excited state & Band gap. The author has an hindex of 13, co-authored 18 publications receiving 394 citations. Previous affiliations of Zhenyu Guo include University of Washington & University of Science and Technology of China.
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Potential Application of Novel Boron-Doped Graphene Nanoribbon as Oxygen Reduction Reaction Catalyst
TL;DR: Using density functional theory computations, the potentials of a novel boron-doped graphene nanoribbon (BGNR) as an excellent electrocatalyst for ORR in an acidic environment were explored in this paper.
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Time-Domain Ab Initio Study of Phonon-Induced Relaxation of Plasmon Excitations in a Silver Quantum Dot
TL;DR: In this paper, the authors investigated the relaxation of plasmon excitations through the phonon channel in a silver nanocrystal with a surface-hopping Kohn-Sham density functional theory in the time domain.
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Real-Time Propagation of the Reduced One-Electron Density Matrix in Atom-Centered Orbitals: Application to Electron Injection Dynamics in Dye-Sensitized TiO2 Clusters
TL;DR: Wang et al. as mentioned in this paper proposed a method to solve the problem of artificial neural networks in the context of artificial intelligence. National Science Foundation of China [20673104, 50121202], National Basic Research Program of China (NBP) [2004CB719901, 2006CB922004]
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Theoretical investigation of the singlet–triplet splittings for carbazole-based thermally activated delayed fluorescence emitters
Ke Liang,Cai-Jun Zheng,Cai-Jun Zheng,Kai Wang,Kai Wang,Wei Liu,Wei Liu,Zhenyu Guo,Youyong Li,Xiaohong Zhang +9 more
TL;DR: The results indicate that the adiabatic excitation energy method with the B3LYP functional is a general and accurate way to predict the ΔESTs of Cz-based TADF emitters.
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Fast Energy Relaxation by Trap States Decreases Electron Mobility in TiO2 Nanotubes: Time-Domain Ab Initio Analysis.
TL;DR: It is demonstrated that oxygen vacancies, which are common in TiO2, accelerate nonradiative energy losses by an order of magnitude and rationalize the unforeseen experimental observations and provide the atomistic basis for improving the structure and charge transport byTiO2 nanotubes.