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using both classical and finite element methods (FEM). Review detailed part or assembly definition prior to production release. Examine structural or material discrepancies and create associated
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; Defect nucleation; Density functional theory; Embedded atom method; Finite element modeling; Molecular dynamics; Multiscale modeling; Nanoindentation; Nanomechanics; Eligibility Citizenship: Open to U.S
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analysis using finite elements of various mechanical assemblies and components when subjected to static, non-linear loads, dynamic, thermal, and/or seismic loads Regulatory destructive testing of Type A
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composite material response or material signal interactions using finite element, analytical or numerical approaches. • Experience with scientific data analysis programming languages such as or Python
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and timeframe Different methods will be used to address the Objectives given above. Objective 1: GIS analysis of historic maps and aerial imagery Potentially capture of new UAV imagery Objective 2
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. Experience related to fluid, cryogen, pressure, flow rate, and gas sensors and instrumentation. Computer-aided design (CAD) experience and demonstrated proficiency (SolidWorks™ preferred). Finite-element
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without expensive die tryouts and new model development costs. In addition, CP-FEM (crystal plasticity-finite element method) modeling allows development of constitutive laws for new materials based
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is to develop a modeling framework including the use of Random-Walk method to predict NMR measurements, pore-scale finite-element modeling on 3D digital models, generated from CT-images to predict
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thermomechanical finite element modeling, CALPHAD-based thermodynamics, and crystal plasticity and to both powder-scale and atomic-scale simulations. Emphasis will be on integration of model predictions with
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strain rates and temperatures. Identifying material properties and constitutive model parameters from the integrated data sets currently focuses on the finite element model updating (FEMU) method, but