Unraveling Dynamic Transitions in Time-Resolved Biomolecular Motions by A Dressed Diffusion Model

Kaicheng Zhu; Haibin Su

doi:10.1021/acs.jpca.9b08142

Unraveling Dynamic Transitions in Time-Resolved Biomolecular Motions by A Dressed Diffusion Model

Kaicheng Zhu, Haibin Su^*

^*Corresponding author for this work

Department of Chemistry

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

6 Citations (Scopus)

Abstract

Recent experimental data reveal the complexity of diffusion dynamics beyond the scope of classical Brownian dynamics. The particles exhibit diverse diffusive motions from the anomalous toward classical diffusion over a wide range of temporal scales. Here a dressed diffusion model is developed to account for non-Brownian phenomena. By coupling the particle dynamics with a local field, the dressed diffusion model generalizes the Langevin equation through coupled damping kernels and generates the salient feature of time-dependent diffusion dynamics reported in the experimental measurements of biomolecules. The dressed diffusion model provides one quantitative aspect for future endeavors in this rapid-growing field.

Original language	English
Pages (from-to)	613-617
Number of pages	5
Journal	Journal of Physical Chemistry A
Volume	124
Issue number	4
DOIs	https://doi.org/10.1021/acs.jpca.9b08142
Publication status	Published - 30 Jan 2020

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Publisher Copyright:
Copyright © 2019 American Chemical Society.

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10.1021/acs.jpca.9b08142

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title = "Unraveling Dynamic Transitions in Time-Resolved Biomolecular Motions by A Dressed Diffusion Model",

abstract = "Recent experimental data reveal the complexity of diffusion dynamics beyond the scope of classical Brownian dynamics. The particles exhibit diverse diffusive motions from the anomalous toward classical diffusion over a wide range of temporal scales. Here a dressed diffusion model is developed to account for non-Brownian phenomena. By coupling the particle dynamics with a local field, the dressed diffusion model generalizes the Langevin equation through coupled damping kernels and generates the salient feature of time-dependent diffusion dynamics reported in the experimental measurements of biomolecules. The dressed diffusion model provides one quantitative aspect for future endeavors in this rapid-growing field.",

author = "Kaicheng Zhu and Haibin Su",

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AU - Zhu, Kaicheng

AU - Su, Haibin

PY - 2020/1/30

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N2 - Recent experimental data reveal the complexity of diffusion dynamics beyond the scope of classical Brownian dynamics. The particles exhibit diverse diffusive motions from the anomalous toward classical diffusion over a wide range of temporal scales. Here a dressed diffusion model is developed to account for non-Brownian phenomena. By coupling the particle dynamics with a local field, the dressed diffusion model generalizes the Langevin equation through coupled damping kernels and generates the salient feature of time-dependent diffusion dynamics reported in the experimental measurements of biomolecules. The dressed diffusion model provides one quantitative aspect for future endeavors in this rapid-growing field.

AB - Recent experimental data reveal the complexity of diffusion dynamics beyond the scope of classical Brownian dynamics. The particles exhibit diverse diffusive motions from the anomalous toward classical diffusion over a wide range of temporal scales. Here a dressed diffusion model is developed to account for non-Brownian phenomena. By coupling the particle dynamics with a local field, the dressed diffusion model generalizes the Langevin equation through coupled damping kernels and generates the salient feature of time-dependent diffusion dynamics reported in the experimental measurements of biomolecules. The dressed diffusion model provides one quantitative aspect for future endeavors in this rapid-growing field.

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UR - https://openalex.org/W2979641226

UR - https://www.scopus.com/pages/publications/85074168912

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EP - 617

JO - Journal of Physical Chemistry A

JF - Journal of Physical Chemistry A

IS - 4

ER -

Unraveling Dynamic Transitions in Time-Resolved Biomolecular Motions by A Dressed Diffusion Model

Abstract

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