CP2K Open Source Molecular Dynamics

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positions [2016/12/06 10:52] ibethunepositions [2017/02/13 13:36] ibethune
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 Open positions related to CP2K can be posted on this page. Update status as needed. Open positions related to CP2K can be posted on this page. Update status as needed.
  
-===== Research Associate: Molecular Dynamics of Hydrothermal Solutions [ posted: 2016-12-06, status: Open] =====+===== Research Associate: Molecular Dynamics of Hydrothermal Solutions [ posted: 2016-12-06, status: Closed] =====
  
 The School of Earth Sciences seeks a Senior Research Associate in the field geochemistry and physical chemistry. The researcher will be part of a three-year NERC funded project that sets out to predict and understand metal complexation in hydrothermal fluids using first-principles molecular dynamics simulations (using CP2K).  From these simulations, we hope to develop thermodynamic models for the complexation of the post-transition metals Pb, Sn, In and Ga from 0-1000C, 1-5kb.  These models will enable the earth science community to perform reactive-transport simulations of a variety of ore-forming environments to understand the geochemical controls on ore-deposition formation. The work from this project will also enable the development of hydrometallalurgical extraction technologies.   The researcher will have access to the supercomputing facilities at Bristol and also be able to interact with the experimental group in the school of Earth Sciences.  We intend to also develop collaborative work with several industrial partners in the mining and metal-processing sector. The School of Earth Sciences seeks a Senior Research Associate in the field geochemistry and physical chemistry. The researcher will be part of a three-year NERC funded project that sets out to predict and understand metal complexation in hydrothermal fluids using first-principles molecular dynamics simulations (using CP2K).  From these simulations, we hope to develop thermodynamic models for the complexation of the post-transition metals Pb, Sn, In and Ga from 0-1000C, 1-5kb.  These models will enable the earth science community to perform reactive-transport simulations of a variety of ore-forming environments to understand the geochemical controls on ore-deposition formation. The work from this project will also enable the development of hydrometallalurgical extraction technologies.   The researcher will have access to the supercomputing facilities at Bristol and also be able to interact with the experimental group in the school of Earth Sciences.  We intend to also develop collaborative work with several industrial partners in the mining and metal-processing sector.
positions.txt · Last modified: 2023/10/10 16:37 by tkuehne