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of interest include (but not limited to) molecular mechanisms and nonequilibrium thermodynamics in living systems responsible for important regulatory functions such as signal transduction, molecular motor
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enable the simulation and study of phenomena such as novel states of matter like quantum glasses, molecular dynamics and quantum thermodynamics. The project is primarily experimental and will be carried
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College of Chemistry and Molecular Engineering, Peking University | London, England | United Kingdom | about 24 hours ago
and develop predictive models of tissue architecture and cell community dynamics using tools inspired by ecology and geospatial science. Spatial omics technologies are revolutionising our ability
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networks and nonequilibrium thermodynamics of living systems. Current areas of interest include (but not limited to) molecular mechanisms and nonequilibrium thermodynamics in living systems responsible
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and development activities in the fields of atomistic simulations, including density functional theory, machine learning, and molecular dynamics. The work involves theoretical and experimental research
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multistate-multiphysics deep learning potentials and polarizable embedding methodology to simulate photoinduced charge-transfer dynamics in multichromophoric systems, such as photosynthetic reaction centers
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higher education institution in conjunction with an R&D unit in Chemistry, Biochemistry or related fields. Knowledge of protein modeling, virtual screening and classical molecular dynamics. In case
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, materials science, or a related discipline Advanced knowledge of rheology, fluid dynamics, and microfluidics to design and execute experiments simulating real-world conditions Demonstrated interest in soft
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Plan / Goals to be achieved: The candidate will join a dynamic translational research team, within the framework of a strategic collaboration with a pharmaceutical company, with the goal of developing
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of research. These include: Computational physics, including statistical mechanics, biophysics, fluid mechanics, quantum physics, and molecular dynamics Numerical methods for partial differential equations and