Potential energy surface of excited semiconductors: Graphene quantum dot and BODIPY

Colherinhas Guilherme; Fileti Eudes Eterno; Chaban Vitaly V.

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Potential energy surface of excited semiconductors: Graphene quantum dot and BODIPY

机译：激发半导体的势能面：石墨烯量子点和BODIPY

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Binding energy (BE) is an important descriptor in chemistry, which determines thermodynamics and phase behavior of a given substance. BE between two molecules is not directly accessible from the experiment. It has to be reconstructed from cohesive energies, vaporization heats, etc. We report BE for the excited states of two semiconductor molecules - boron-dipyrromethene (BODIPY) and graphene quantum dot (GQD) - with water. We show, for the first time, that excitation increases BE twofold at an optimal separation (energy minimum position), whereas higher separations lead to higher differences. Interestingly, the effects of excitation are similar irrespective of the dominant binding interactions (van der Waals or electrostatic) in the complex. This new knowledge is important for simulations of the excited semiconductors by simplified interaction functions. (C) 2016 Elsevier B.V. All rights reserved.

机译：结合能（BE）是化学中的重要描述词，它决定了给定物质的热力学和相行为。实验无法直接访问两个分子之间的BE。它必须通过内聚能，汽化热等进行重建。我们报道了BE对两个半导体分子-硼-二吡咯亚甲基（BODIPY）和石墨烯量子点（GQD）的激发态与水的关系。我们首次表明，在最佳间隔（能量最小位置）处，激发能增加BE两倍，而较高的间隔导致较高的差异。有趣的是，不管复合物中的主要结合相互作用（范德华或静电）如何，激发的作用都是相似的。通过简化的相互作用函数，这一新知识对于受激半导体的仿真非常重要。（C）2016 Elsevier B.V.保留所有权利。

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《Chemical Physics: A Journal Devoted to Experimental and Theoretical Research Involving Problems of Both a Chemical and Physical Nature》 |2016年第null期|共6页
作者
Colherinhas Guilherme; Fileti Eudes Eterno; Chaban Vitaly V.;
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正文语种 eng
中图分类物理化学（理论化学）、化学物理学;
关键词
Graphene; BODIPY; Water; Binding energy; TDDFT; Excited states;

机译：石墨烯;BODIPY;水;结合能;TDDFT;激发态;

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1. Potential energy surface of excited semiconductors: Graphene quantum dot and BODIPY [J] . Colherinhas Guilherme, Fileti Eudes Eterno, Chaban Vitaly V. Chemical Physics: A Journal Devoted to Experimental and Theoretical Research Involving Problems of Both a Chemical and Physical Nature . 2016,第Null期

机译：激发半导体的势能面：石墨烯量子点和BODIPY
2. Polaronic correction to the first excited electronic energy level in an anisotropic semiconductor quantum dot [J] . Feng DH, Xu ZZ, Jia TQ, The European physical journal, B. Condensed matter physics . 2005,第1期

机译：对各向异性半导体量子点中的第一激发电子能级进行极化校正
3. Polaronic correction to the first excited electronic energy level in semiconductor quantum dots with parabolic confinement [J] . Mukhopadhyay S., Chatterjee A. Physics Letters, A . 1998,第1a2期

机译：用抛物线约束对半导体量子点中的第一激发电子能级进行极化校正
4. Interaction of Graphene Quantum Dots with Bulk Semiconductor Surfaces [C] . P. K. Mohapatra, Dushyant Kushavah, J. Mohapatra, International Conference on Condensed Matter Physics . 2015

机译：石墨烯量子点与散装半导体表面的相互作用
5. Electron spin dynamics in quantum dots, and the roles of charge transfer excited states in diluted magnetic semiconductors [D] . Liu, William K. 2007

机译：量子点中的电子自旋动力学以及稀磁半导体中电荷转移激发态的作用
6. Bioluminescence-Based Energy Transfer Using Semiconductor Quantum Dots as Acceptors [O] . Anirban Samanta, Igor L. Medintz 2020

机译：使用半导体量子点作为受体的基于生物发光的能量转移
7. Energy Structure of Two-Dimensional Graphene-Semiconductor Quantum Dot [O] . Jin Tong Wang, Guang-Lin Zhao, Diola Bagayoko, 2013

机译：二维石墨烯-半导体量子点的能量结构

Potential energy surface of excited semiconductors: Graphene quantum dot and BODIPY

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