Pseudo-Hydrogen Passivation: A Novel Way to Calculate Absolute Surface Energy of Zinc Blende (111)/(͞1 ͞1 ͞1) Surface

Zhang, Yiou; Zhang, Jingzhao; Tse, Kinfai; Wong, Lun M.; Chan, Chun-Kit; Deng, Bei; Zhu, Junyi

doi:10.1038/srep20055

Cited by 31 publications

(33 citation statements)

References 41 publications

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“…This can be done either by artificially saturating them, e.g. with (pseudo)hydrogen atoms, [38][39][40][41][42][43][44] or by employing density embedding methods. 45,16,31,[46][47][48][49][50] In the latter case, the cluster, which is computed using an expensive method, is embedded into a surrounding material that is significantly more extended, but described by a computationally less demanding method (often, specially designed pseudopotentials).…”

Section: Cluster Models Of Hybrid Inorganic/organic Interfacesmentioning

confidence: 99%

First-principles calculations of hybrid inorganic–organic interfaces: from state-of-the-art to best practice

Hofmann

Zojer

Hörmann

et al. 2021

Phys. Chem. Chem. Phys.

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Section: Cluster Models Of Hybrid Inorganic/organic Interfacesmentioning

confidence: 99%

First-principles calculations of hybrid inorganic–organic interfaces: from state-of-the-art to best practice

Hofmann

Zojer

Hörmann

et al. 2021

Phys. Chem. Chem. Phys.

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“…Here, to reduce the computational cost, we passivate the surface with pseudo‐H atoms. The pseudo‐H atoms carry fractional charges to neutralize the surface atoms by satisfying the electron counting rule . For tetrahedrally coordinated CdS, every Cd or S atom is surrounded by four S or Cd atoms.…”

Section: Resultsmentioning

confidence: 99%

Hybrid density functional study on the electronic structures and properties of P3HT‐PbS and P3HT‐CdS hybrid interface for photovoltaic applications

Nguyen

Shim

2018

J Comput Chem

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The efficiency of charge transport mainly depends on the interfacial energy level alignment between the conjugated polymer and the inorganic substrate. It provides an accurate understanding, predicting as well as controlling the optimal power conversion efficiency of various type of hybrid photovoltaic systems. In this article, we use hybrid functional (HSE06) to study the electronic structures and properties at the interface of poly(3‐hexylthiophene)(P3HT)/CdS and P3HT/PbS for solar cell applications. We found that the dangling bonds at the inorganic surface introduce in‐gap states and greatly reduce the device performance. We used pseudo‐hydrogen atoms as the passivation agent to remove the dangling bonds and eliminate the in‐gap states to construct the energy alignment at the hybrid interface. The calculated interfacial density of states reveal a better performance in P3HT/CdS, compared to P3HT/PbS. P3HT/CdS possesses a LUMOP3HT/CBMCdS and HOMOP3HT/VBMCdS energy offset large enough for sufficient exciton separation across the interface and prevents charge recombination. In contrast, the reason for low power conversion efficiency in P3HT/PbS lies on its HOMOP3HT/VBMPbS offset which is too small to break the exciton binding energy for charge separation. Moreover, we reported the dependency of the energy level alignment and open circuit voltage on the interfacial molecular orientations. Our DFT calculation can be used to predict candidate materials for the development of efficiency optoelectronic devices. © 2018 Wiley Periodicals, Inc.

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“…The bottom layer had to be passivated with a pseudohydrogen layer for subsequent DFT simulations. [ 57 ] To create the pseudo‐hydrogen atoms we defined Change Element as “H1.5” so that hydrogen atoms possess 1.5 electron charges each. After saving the file (ctrl + s), we opened it in a text editor and added a 15 Å vacuum along the [111] direction; we could then relax the system with VASP to find the optimal positions for the Cu, O, and pseudo‐H atoms.…”

Section: Case Studiesmentioning

confidence: 99%

NanoMaterialsCAD: Flexible Software for the Design of Nanostructures

Nikoulis

Grammatikopoulos

Steinhauer

et al. 2020

Advcd Theory and Sims

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NanoMaterialsCAD is a new open source tool dedicated to the creation, manipulation, and 3D visualization of crystalline structures at the nanoscale. It is designed for preprocessing atomistic configurations to be used as input for atomistic (e.g., molecular dynamics or Monte Carlo) or ab initio (e.g., density functional theory) computer simulations. It offers several tools for designing complex nanostructures (including nanoparticles, nanowires, nanotubes, nanoscrolls, etc., and combinations/permutations of them) which are either lacking or cumbersome in other existing packages. Through its intuitive graphical user interface (GUI) it enables facile ways to design and modify the size/shape and relative positions of nanoobjects while observing the changes in real time. NanoMaterialsCAD is written in C++, and exploits Open Graphics Library (OpenGL) (for the GUI), Win32API (for interaction with Windows), and Assembly (for fast data management). The source code and executable file are available for download from GitHub (https://github.com/cossphy/NanoMaterialsCAD). It is aspired that NanoMaterialsCAD will be adopted by the nanomaterials modeling community as a valuable resource; to this end it will be kept improving, incorporating more nanostructures, and adding extra functionalities to its toolbox.

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Pseudo-Hydrogen Passivation: A Novel Way to Calculate Absolute Surface Energy of Zinc Blende (111)/(͞1 ͞1 ͞1) Surface

Cited by 31 publications

References 41 publications

First-principles calculations of hybrid inorganic–organic interfaces: from state-of-the-art to best practice

First-principles calculations of hybrid inorganic–organic interfaces: from state-of-the-art to best practice

Hybrid density functional study on the electronic structures and properties of P3HT‐PbS and P3HT‐CdS hybrid interface for photovoltaic applications

NanoMaterialsCAD: Flexible Software for the Design of Nanostructures

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