A Constrained CASSCF(2,2) Approach to Study Electron Transfer between a Molecule and Metal Cluster

Xinchun Wu; Junhan Chen; Joseph Subotnik

doi:10.1021/acs.jpca.4c04843

A Constrained CASSCF(2,2) Approach to Study Electron Transfer between a Molecule and Metal Cluster

Xinchun Wu
, Junhan Chen
, Joseph Subotnik

Chemistry

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

We have implemented a constrained CASSCF(2,2) calculation so as to study thermal electron transfer between a chlorine ion and a cluster of lithium atoms of variable size (from 1 to 17). Our calculations illustrate how the geometry of the ground state-charge transfer state crossing point (as well as the strength of a diabatic coupling) can depend sensitively on the number of metal ions (i.e., the size of the cluster) and the relative positioning of the donor and acceptor. Thus, this set of calculations is an initial step toward understanding the transition from homogeneous to heterogeneous electron transfer. In the future, these constrained calculations should allow us to model still far larger systems, ideally opening up a pathway to study meaningful electrochemical phenomena.

Original language	English (US)
Pages (from-to)	9538-9550
Number of pages	13
Journal	Journal of Physical Chemistry A
Volume	128
Issue number	43
DOIs	https://doi.org/10.1021/acs.jpca.4c04843
State	Published - Oct 31 2024

All Science Journal Classification (ASJC) codes

Physical and Theoretical Chemistry

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10.1021/acs.jpca.4c04843

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title = "A Constrained CASSCF(2,2) Approach to Study Electron Transfer between a Molecule and Metal Cluster",

abstract = "We have implemented a constrained CASSCF(2,2) calculation so as to study thermal electron transfer between a chlorine ion and a cluster of lithium atoms of variable size (from 1 to 17). Our calculations illustrate how the geometry of the ground state-charge transfer state crossing point (as well as the strength of a diabatic coupling) can depend sensitively on the number of metal ions (i.e., the size of the cluster) and the relative positioning of the donor and acceptor. Thus, this set of calculations is an initial step toward understanding the transition from homogeneous to heterogeneous electron transfer. In the future, these constrained calculations should allow us to model still far larger systems, ideally opening up a pathway to study meaningful electrochemical phenomena.",

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AU - Chen, Junhan

AU - Subotnik, Joseph

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Y1 - 2024/10/31

N2 - We have implemented a constrained CASSCF(2,2) calculation so as to study thermal electron transfer between a chlorine ion and a cluster of lithium atoms of variable size (from 1 to 17). Our calculations illustrate how the geometry of the ground state-charge transfer state crossing point (as well as the strength of a diabatic coupling) can depend sensitively on the number of metal ions (i.e., the size of the cluster) and the relative positioning of the donor and acceptor. Thus, this set of calculations is an initial step toward understanding the transition from homogeneous to heterogeneous electron transfer. In the future, these constrained calculations should allow us to model still far larger systems, ideally opening up a pathway to study meaningful electrochemical phenomena.

AB - We have implemented a constrained CASSCF(2,2) calculation so as to study thermal electron transfer between a chlorine ion and a cluster of lithium atoms of variable size (from 1 to 17). Our calculations illustrate how the geometry of the ground state-charge transfer state crossing point (as well as the strength of a diabatic coupling) can depend sensitively on the number of metal ions (i.e., the size of the cluster) and the relative positioning of the donor and acceptor. Thus, this set of calculations is an initial step toward understanding the transition from homogeneous to heterogeneous electron transfer. In the future, these constrained calculations should allow us to model still far larger systems, ideally opening up a pathway to study meaningful electrochemical phenomena.

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A Constrained CASSCF(2,2) Approach to Study Electron Transfer between a Molecule and Metal Cluster

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