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Field
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do: Design, fabricate, characterize, and optimize electrochemical biosensing technologies for real-time detection. Develop and implement novel surface chemistries to improve sensor performance
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team. Learn more about the innovative work led by Dr. Don Ingber here: https://wyss.harvard.edu/technology/human-organs-on-chips/ . What you’ll do: Design, fabricate, characterize, and optimize
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ecosystem impacts. Biogeochemical models (BGC) play a critical role in the MRV framework by providing numerical simulations to evaluate air-sea CO₂ fluxes and associated biogeochemical changes. However
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-reviewed venues. Examples of NESAP project themes: Development, performance analysis and optimization of end-to-end science workflows, including those originating at DOE facilities. Deployment
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specialized differentiable numerical solvers for trajectory optimization that generate informed motion trajectories for contact-rich manipulation tasks, handling complex dynamics and physical constraints
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experimental data and ensure optimal use of the results. - Contribute to the preparation of scientific publications, reports, and dissemination activities, promoting the project results within the scientific
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: Development, performance analysis and optimization of end-to-end science workflows, including those originating at DOE facilities. Deployment of capabilities such as AI training and inference at scale, and
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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
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of buildings with standard lightweight façades. Development of an innovative numerical model in EnergyPlus that allows for the simulation of buildings with dynamic thermal insulation systems. Implementation
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numerical solvers for 2D and 3D phase field models Develop HPC-ready simulation pipelines for large-scale rupture and fracture-fluid systems Optimize performance for modern architectures including GPUs and