| 项目编号: | 1708968
|
| 项目名称: | Understanding Surface Wetting and Vapor Adsorption Induced Degradation Pathways of Organic-Inorganic Hybrid Perovskites through Predictive Atomistic Simulations |
| 作者: | Shangchao Lin
|
| 承担单位: | Florida State University
|
| 批准年: | 2017
|
| 开始日期: | 2017-08-01
|
| 结束日期: | 2020-07-31
|
| 资助金额: | 227972
|
| 资助来源: | US-NSF
|
| 项目类别: | Standard Grant
|
| 国家: | US
|
| 语种: | 英语
|
| 特色学科分类: | Engineering - Chemical, Bioengineering, Environmental, and Transport Systems
|
| 英文关键词: | hybrid perovskite
; surface-to-surface
; density functional theory-based quantum mechanical simulation
; quantum mechanical simulation
; quantum mechanics-informed classical molecular dynamics simulation
; project
; predictive molecular dynamics
; surface stability
; surface property
; inorganic component
; vapor adsorption
; inorganic material characteristic
; surface wetting
; ab initio molecular dynamics simulation
; vapor-resistive ligand
|
| 英文摘要: | Hybrid perovskites, a class of materials that have organic and inorganic components, have emerged as promising light absorbers for photovoltaic cells and emitters for light-emitting diodes. These new materials feature the integration of useful organic and inorganic material characteristics, thereby enabling unique electronic, magnetic, and/or optical properties. The surface properties of hybrid perovskites are key for practical applications yet have been largely unexplored. The instability of hybrid perovskites also remains a technological bottleneck for their commercialization. This research project involves computational and data-enabled research and aims to understand the surface stability and interfacial, or surface-to-surface, compatibility of hybrid perovskites with water and vapor under different ambient humidity levels. Such understanding will further enable the design and use of stable hybrid perovskites systems for practical applications in solar energy harvesting and energy-efficient lighting. This project supports the training and education of undergraduate and graduate students as well as broader educational efforts for the research community. The researchers on this project are developing an Integrated Computational Materials Engineering-related curriculum for the new Materials Science & Engineering program at Florida State University (FSU). They are also hosting the FSU Young Scholars Program to encourage Florida high school students to pursue careers in STEM fields.
This project involves theoretical and computational research to shed light on experimental observations and to predict materials properties at the hybrid perovskite-water interface that are difficult to access experimentally. Density functional theory-based quantum mechanical simulations have been used extensively to model hybrid perovskites. However, the time scales associated with dynamic processes are comparable to, or much longer than, the typical 100 picosecond time scale accessible using ab initio molecular dynamics simulations. In addition, the length scales that can be modeled using quantum mechanical simulations is still limited to a few nm, which does not allow for direct prediction of the formation of material structures that are larger than 10 nanometers, such as polycrystalline grain-boundaries. Therefore, quantum mechanics-informed classical molecular dynamics simulations would be an ideal technique to bridge this gap. The development of a predictive molecular dynamics force field to capture the structural, surface, and interfacial properties of hybrid perovskites inevitably involves parameterization based on reproducing relevant experimental data or quantum mechanical information. To evaluate the fidelity and sensitivity of the developed force-field parameters, uncertainty quantification methods, such as Bayesian statistics, are being used, and Markov chain Monte Carlo sampling of the various force-field parameters against target material properties are being conducted. The synergistic combination of potential of mean force calculations with surface wetting, vapor adsorption, and reaction kinetic theories can lead to accurate perovskite lifetime predictions. The development of the new force fields will be a major contribution to the field, because the new force fields can then be transferrable to model the thermal, ionic transport, and interfacial properties of single and polycrystalline perovskites. With this fundamental understanding in hand, are designing chemically-stable hybrid perovskites passivated by water- and vapor-resistive ligands. |
| 资源类型: | 项目
|
| 标识符: | http://119.78.100.158/handle/2HF3EXSE/89681
|
| Appears in Collections: | 全球变化的国际研究计划
科学计划与规划
|
|
There are no files associated with this item.
|
| Recommended Citation: | |
Shangchao Lin. Understanding Surface Wetting and Vapor Adsorption Induced Degradation Pathways of Organic-Inorganic Hybrid Perovskites through Predictive Atomistic Simulations. 2017-01-01.
|
|
|