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Autores principales: Saurav, Sameer, Das, Debjit, Javed, Ramsha, Nair, Nisanth N.
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2509.05068
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author Saurav, Sameer
Das, Debjit
Javed, Ramsha
Nair, Nisanth N.
author_facet Saurav, Sameer
Das, Debjit
Javed, Ramsha
Nair, Nisanth N.
contents Temperature-accelerated sliced sampling (TASS) is a well-established enhanced sampling method that facilitates exhaustive exploration of high-dimensional collective variable (CV) space through directed sampling employing a combination of umbrella restraining biases, metadynamics biases, and temperature acceleration of CVs. In this work, we broaden the applicability of TASS by introducing a protocol for computing rate constants of barrier crossing events. The challenge addressed here is to recover kinetics from free energy data computed from different slices of the TASS simulation. The proposed protocol utilizes artificial neural networks based representation of high-dimensional free energy landscapes, and Infrequent Metadynamics. We demonstrate the accuracy of the approach by obtaining rate constants for the conformational change of alanine dipeptide in vacuo, the unbinding of benzamidine from trypsin, and the unbinding of aspirin from $β$-cyclodextrin.
format Preprint
id arxiv_https___arxiv_org_abs_2509_05068
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Kinetics of Barrier Crossing Events from Temperature Accelerated Sliced Sampling Simulations
Saurav, Sameer
Das, Debjit
Javed, Ramsha
Nair, Nisanth N.
Chemical Physics
Temperature-accelerated sliced sampling (TASS) is a well-established enhanced sampling method that facilitates exhaustive exploration of high-dimensional collective variable (CV) space through directed sampling employing a combination of umbrella restraining biases, metadynamics biases, and temperature acceleration of CVs. In this work, we broaden the applicability of TASS by introducing a protocol for computing rate constants of barrier crossing events. The challenge addressed here is to recover kinetics from free energy data computed from different slices of the TASS simulation. The proposed protocol utilizes artificial neural networks based representation of high-dimensional free energy landscapes, and Infrequent Metadynamics. We demonstrate the accuracy of the approach by obtaining rate constants for the conformational change of alanine dipeptide in vacuo, the unbinding of benzamidine from trypsin, and the unbinding of aspirin from $β$-cyclodextrin.
title Kinetics of Barrier Crossing Events from Temperature Accelerated Sliced Sampling Simulations
topic Chemical Physics
url https://arxiv.org/abs/2509.05068