Monte-Carlo simulations with an ML potential demonstrate that coherency strain removes the Ag-Cu miscibility gap in Ag_xCu_{1-x}GaSe2, producing complete mixing.
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Laser-enhanced contact optimization recovers fill factor in under-fired cavitated Ag paste on PERC cells by improving localized conduction at suboptimal firing temperatures.
A review of LECO in silicon photovoltaics that frames it as a multiphysics process and outlines a predictive workflow using regime maps and reduced state metrics for stable contact optimization.
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Chemo-mechanical coupling stabilizes mixed $\mathrm{Ag}_{x}\mathrm{Cu}_{1-x}\mathrm{GaSe}_{2}$ solar-cell absorbers: Insights from Monte-Carlo simulations assisted by ab initio informed machine-learning potentials
Monte-Carlo simulations with an ML potential demonstrate that coherency strain removes the Ag-Cu miscibility gap in Ag_xCu_{1-x}GaSe2, producing complete mixing.
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Mitigating the contact resistance limitation of cavitated fine line Ag paste by Laser-Enhanced Contact Optimization
Laser-enhanced contact optimization recovers fill factor in under-fired cavitated Ag paste on PERC cells by improving localized conduction at suboptimal firing temperatures.
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Laser-Enhanced Contact Optimization in Silicon Photovoltaics: Mechanisms, Reliability, and Predictive Process Design
A review of LECO in silicon photovoltaics that frames it as a multiphysics process and outlines a predictive workflow using regime maps and reduced state metrics for stable contact optimization.