The adaptive buffered force QM/MM method in the CP2K and AMBER software packages |
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| Authors: | Letif Mones Andrew Jones Andreas W Götz Teodoro Laino Ross C Walker Ben Leimkuhler Gábor Csányi Noam Bernstein |
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| Institution: | 1. Engineering Department, University of Cambridge, Cambridge, United Kingdom;2. Institute for Condensed Matter and Complex Systems, School of Physics and Astronomy, University of Edinburgh, Edinburgh, United Kingdom;3. San Diego Supercomputer Center, University of California San Diego, La Jolla, California;4. Mathematical and Computational Sciences Department, IBM Research–Zurich, Rüschlikon, Switzerland;5. Department of Chemistry and Biochemistry, University of California San Diego, California;6. The Maxwell Institute and School of Mathematics, University of Edinburgh, Edinburgh, United Kingdom;7. Center for Computational Material Science, Naval Research Laboratory, Washington, DC |
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| Abstract: | The implementation and validation of the adaptive buffered force (AdBF) quantum‐mechanics/molecular‐mechanics (QM/MM) method in two popular packages, CP2K and AMBER are presented. The implementations build on the existing QM/MM functionality in each code, extending it to allow for redefinition of the QM and MM regions during the simulation and reducing QM‐MM interface errors by discarding forces near the boundary according to the buffered force‐mixing approach. New adaptive thermostats, needed by force‐mixing methods, are also implemented. Different variants of the method are benchmarked by simulating the structure of bulk water, water autoprotolysis in the presence of zinc and dimethyl‐phosphate hydrolysis using various semiempirical Hamiltonians and density functional theory as the QM model. It is shown that with suitable parameters, based on force convergence tests, the AdBF QM/MM scheme can provide an accurate approximation of the structure in the dynamical QM region matching the corresponding fully QM simulations, as well as reproducing the correct energetics in all cases. Adaptive unbuffered force‐mixing and adaptive conventional QM/MM methods also provide reasonable results for some systems, but are more likely to suffer from instabilities and inaccuracies. © 2015 The Authors. Journal of Computational Chemistry Published by Wiley Periodicals, Inc. |
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| Keywords: | quantum‐mechanics/molecular‐mechanics adaptive quantum‐mechanics/molecular‐mechanics force‐mixing multiscale |
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