dorsal/arxiv
View SchemaComparison of free energy methods for molecular systems
| Authors | F. Marty Ytreberg, Robert H. Swendsen, Daniel M. Zuckerman |
|---|---|
| Categories | |
| ArXiv ID | physics/0602088 |
| URL | https://arxiv.org/abs/physics/0602088 |
| DOI | 10.1063/1.2378907 |
Abstract
We present a detailed comparison of computational efficiency and precision for several free energy difference ($\Delta F$) methods. The analysis includes both equilibrium and non-equilibrium approaches, and distinguishes between uni-directional and bi-directional methodologies. We are primarily interested in comparing two recently proposed approaches, adaptive integration and single-ensemble path sampling, to more established methodologies. As test cases, we study relative solvation free energies, of large changes to the size or charge of a Lennard-Jones particle in explicit water. The results show that, for the systems used in this study, both adaptive integration and path sampling offer unique advantages over the more traditional approaches. Specifically, adaptive integration is found to provide very precise long-simulation $\Delta F$ estimates as compared to other methods used in this report, while also offering rapid estimation of $\Delta F$. The results demonstrate that the adaptive integration approach is the best overall method for the systems studied here. The single-ensemble path sampling approach is found to be superior to ordinary Jarzynski averaging for the uni-directional, ``fast-growth'' non-equilibrium case. Closer examination of the path sampling approach on a two-dimensional system suggests it may be the overall method of choice when conformational sampling barriers are high. However, it appears that the free energy landscapes for the systems used in this study have rather modest configurational sampling barriers.
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"abstract": "We present a detailed comparison of computational efficiency and precision\nfor several free energy difference ($\\Delta F$) methods. The analysis includes\nboth equilibrium and non-equilibrium approaches, and distinguishes between\nuni-directional and bi-directional methodologies. We are primarily interested\nin comparing two recently proposed approaches, adaptive integration and\nsingle-ensemble path sampling, to more established methodologies. As test\ncases, we study relative solvation free energies, of large changes to the size\nor charge of a Lennard-Jones particle in explicit water. The results show that,\nfor the systems used in this study, both adaptive integration and path sampling\noffer unique advantages over the more traditional approaches. Specifically,\nadaptive integration is found to provide very precise long-simulation $\\Delta\nF$ estimates as compared to other methods used in this report, while also\noffering rapid estimation of $\\Delta F$. The results demonstrate that the\nadaptive integration approach is the best overall method for the systems\nstudied here. The single-ensemble path sampling approach is found to be\nsuperior to ordinary Jarzynski averaging for the uni-directional,\n``fast-growth\u0027\u0027 non-equilibrium case. Closer examination of the path sampling\napproach on a two-dimensional system suggests it may be the overall method of\nchoice when conformational sampling barriers are high. However, it appears that\nthe free energy landscapes for the systems used in this study have rather\nmodest configurational sampling barriers.",
"arxiv_id": "physics/0602088",
"authors": [
"F. Marty Ytreberg",
"Robert H. Swendsen",
"Daniel M. Zuckerman"
],
"categories": [
"physics.bio-ph"
],
"doi": "10.1063/1.2378907",
"title": "Comparison of free energy methods for molecular systems",
"url": "https://arxiv.org/abs/physics/0602088"
},
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