A new non-contact steady-state temperature differential radiometry platform measures molybdenum thermal conductivity from 1500-3000 K with 7.9-11% uncertainty and spectral emittance in solid and liquid states over 500-1000 nm.
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High-fidelity multiphysics simulations of laser powder bed fusion melt pools match 2025 NIST experimental data across depth, width, bead height, overlap, and area metrics for varied powder heights and geometries.
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Closing the ultrahigh temperature metrology gap: non-contact thermal conductivity ($\mathrm{k}$) and spectral emittance ($\mathrm{\varepsilon_{\lambda}}$) of molybdenum up to 3200 K
A new non-contact steady-state temperature differential radiometry platform measures molybdenum thermal conductivity from 1500-3000 K with 7.9-11% uncertainty and spectral emittance in solid and liquid states over 500-1000 nm.
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Laser Powder Bed Fusion Melt Pool Dynamics for Different Geometric Variations and Powder Layer Heights: High-Fidelity Multiphysics Modeling vs 2025 NIST Experiments
High-fidelity multiphysics simulations of laser powder bed fusion melt pools match 2025 NIST experimental data across depth, width, bead height, overlap, and area metrics for varied powder heights and geometries.