The tension-activated carbon–carbon bond

Yunyan Sun; Ilia Kevlishvili; Tatiana B. Kouznetsova; Zach P. Burke; Stephen L. Craig; Heather J. Kulik; Jeffrey S. Moore

doi:10.1016/j.chempr.2024.05.012

The tension-activated carbon–carbon bond

Yunyan Sun, Ilia Kevlishvili, Tatiana B. Kouznetsova, Zach P. Burke, Stephen L. Craig, Heather J. Kulik, Jeffrey S. Moore

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

Abstract

Mechanical force drives distinct chemical reactions; yet, its vectoral nature results in complicated coupling with reaction trajectories. Here, we utilize a physical organic model inspired by the classical Morse potential and its differential forms to identify effective force constant (k_eff) and reaction energy (ΔE) as key molecular features that govern mechanochemical kinetics. Through a comprehensive experimental and computational investigation with four norborn-2-en-7-one (NEO) mechanophores, we establish the relationship between these features and the force-dependent energetic changes along the reaction pathways. We show that the complex kinetic behavior of the tensioned bonds is generally and quantitatively predicted by a simple multivariate linear regression based on the two easily computed features with a straightforward workflow. These results demonstrate a general mechanistic framework for mechanochemical reactions under tensile force and provide a highly accessible tool for the large-scale computational screening in the design of mechanophores.

Original language	English (US)
Pages (from-to)	3055-3066
Number of pages	12
Journal	Chem
Volume	10
Issue number	10
DOIs	https://doi.org/10.1016/j.chempr.2024.05.012
State	Published - Oct 10 2024

Keywords

SDG3: Good health and well-being
SDG9: Industry, innovation, and infrastructure
carbon–carbon bond activation
effective force constant
mechanophore
physical organic chemistry
polymer mechanochemistry
reactivity
restoring force triangle

ASJC Scopus subject areas

General Chemistry
Biochemistry
Environmental Chemistry
General Chemical Engineering
Biochemistry, medical
Materials Chemistry

Online availability

10.1016/j.chempr.2024.05.012

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title = "The tension-activated carbon–carbon bond",

abstract = "Mechanical force drives distinct chemical reactions; yet, its vectoral nature results in complicated coupling with reaction trajectories. Here, we utilize a physical organic model inspired by the classical Morse potential and its differential forms to identify effective force constant (keff) and reaction energy (ΔE) as key molecular features that govern mechanochemical kinetics. Through a comprehensive experimental and computational investigation with four norborn-2-en-7-one (NEO) mechanophores, we establish the relationship between these features and the force-dependent energetic changes along the reaction pathways. We show that the complex kinetic behavior of the tensioned bonds is generally and quantitatively predicted by a simple multivariate linear regression based on the two easily computed features with a straightforward workflow. These results demonstrate a general mechanistic framework for mechanochemical reactions under tensile force and provide a highly accessible tool for the large-scale computational screening in the design of mechanophores.",

keywords = "SDG3: Good health and well-being, SDG9: Industry, innovation, and infrastructure, carbon–carbon bond activation, effective force constant, mechanophore, physical organic chemistry, polymer mechanochemistry, reactivity, restoring force triangle",

author = "Yunyan Sun and Ilia Kevlishvili and Kouznetsova, {Tatiana B.} and Burke, {Zach P.} and Craig, {Stephen L.} and Kulik, {Heather J.} and Moore, {Jeffrey S.}",

note = "We thank Shu Wang for the discussion on Morse potential and its derivatives, Dorothy Loudermilk for figure designs, and Toby Woods for X-ray crystallography help. This work was supported by the NSF Center for the Chemistry of Molecularly Optimized Networks (MONET), CHE-2116298 . This work used Expanse at San Diego Supercomputing Center through allocation CHE140073 from the Advanced Cyberinfrastructure Coordination Ecosystem: Services and Support (ACCESS) program, which is supported by National Science Foundation grants # 2138259 , # 2138286 , # 2138307 , # 2137603 , and # 2138296 .",

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AU - Sun, Yunyan

AU - Kevlishvili, Ilia

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AU - Craig, Stephen L.

AU - Kulik, Heather J.

AU - Moore, Jeffrey S.

N1 - We thank Shu Wang for the discussion on Morse potential and its derivatives, Dorothy Loudermilk for figure designs, and Toby Woods for X-ray crystallography help. This work was supported by the NSF Center for the Chemistry of Molecularly Optimized Networks (MONET), CHE-2116298 . This work used Expanse at San Diego Supercomputing Center through allocation CHE140073 from the Advanced Cyberinfrastructure Coordination Ecosystem: Services and Support (ACCESS) program, which is supported by National Science Foundation grants # 2138259 , # 2138286 , # 2138307 , # 2137603 , and # 2138296 .

PY - 2024/10/10

Y1 - 2024/10/10

N2 - Mechanical force drives distinct chemical reactions; yet, its vectoral nature results in complicated coupling with reaction trajectories. Here, we utilize a physical organic model inspired by the classical Morse potential and its differential forms to identify effective force constant (keff) and reaction energy (ΔE) as key molecular features that govern mechanochemical kinetics. Through a comprehensive experimental and computational investigation with four norborn-2-en-7-one (NEO) mechanophores, we establish the relationship between these features and the force-dependent energetic changes along the reaction pathways. We show that the complex kinetic behavior of the tensioned bonds is generally and quantitatively predicted by a simple multivariate linear regression based on the two easily computed features with a straightforward workflow. These results demonstrate a general mechanistic framework for mechanochemical reactions under tensile force and provide a highly accessible tool for the large-scale computational screening in the design of mechanophores.

AB - Mechanical force drives distinct chemical reactions; yet, its vectoral nature results in complicated coupling with reaction trajectories. Here, we utilize a physical organic model inspired by the classical Morse potential and its differential forms to identify effective force constant (keff) and reaction energy (ΔE) as key molecular features that govern mechanochemical kinetics. Through a comprehensive experimental and computational investigation with four norborn-2-en-7-one (NEO) mechanophores, we establish the relationship between these features and the force-dependent energetic changes along the reaction pathways. We show that the complex kinetic behavior of the tensioned bonds is generally and quantitatively predicted by a simple multivariate linear regression based on the two easily computed features with a straightforward workflow. These results demonstrate a general mechanistic framework for mechanochemical reactions under tensile force and provide a highly accessible tool for the large-scale computational screening in the design of mechanophores.

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The tension-activated carbon–carbon bond

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