分离(统计)
吞吐量
高通量筛选
计算机科学
人工智能
机器学习
化学
操作系统
生物化学
无线
作者
Pelin Sezgin,Hasan Can Gülbalkan,Seda Keskın
出处
期刊:JPhys materials
[IOP Publishing]
日期:2024-09-27
卷期号:7 (4): 045006-045006
被引量:3
标识
DOI:10.1088/2515-7639/ad80cd
摘要
Abstract Given the rapidly expanding pool of synthesized and hypothetical metal–organic frameworks (MOFs), testing every single material for SF 6 /N 2 separation by iterative experimental methods or computationally demanding molecular simulations is not practical. In this study, we integrated high-throughput computational screening and machine learning (ML) approaches to evaluate SF 6 /N 2 mixture adsorption and separation performances of over 25 000 different types of synthesized and hypothetical MOFs (hypoMOFs), representing the largest set of structures studied for SF 6 /N 2 separation to date. SF 6 /N 2 mixture adsorption data that we produced for synthesized MOFs using molecular simulations were utilized to develop ML models to accurately and quickly predict SF 6 and N 2 uptakes, SF 6 /N 2 selectivities, SF 6 working capacities, adsorbent performance scores, and regenerabilities of both synthesized and hypoMOFs. Results showed the MOF space that we studied exhibits very high SF 6 /N 2 selectivities in the range of 1.8–4204 at 1 bar in addition to high SF 6 working capacities between 0.04–5.68 mol kg −1 at an adsorption pressure of 1 bar and desorption pressure of 0.1 bar at room temperature. The top-performing MOF adsorbents for SF 6 /N 2 mixture separation were identified to have Zn, Cu, Ni metals; terphenyl, pyridine, naphthalene linkers; and medium pore sizes. Our comprehensive computational approach offers a highly efficient alternative to brute-force computer simulations by enabling the rapid assessment of the MOF adsorbents for SF 6 /N 2 separation and provides molecular insights into the key structural features of the most promising adsorbents.
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