Abstract The microstructure determines the photovoltaic performance of a thin film organic semiconductor film. The relationship between microstructure and performance is usually highly non-linear and expensive to evaluate, thus making microstructure optimization challenging. Here, we show a data-driven approach for mapping the microstructure to photovoltaic performance using deep convolutional neural networks. We characterize this approach in terms of two critical metrics, its generalizability (has it learnt a reasonable map?), and its intepretability (can it produce meaningful microstructure characteristics that influence its prediction?). A surrogate model that exhibits these two features of generalizability and intepretability is particularly useful for subsequent design exploration. We illustrate this by using the surrogate model for both manual exploration (that verifies known domain insight) as well as automated microstructure optimization. We envision such approaches to be widely applicable to a wide variety of microstructure-sensitive design problems.

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photovoltaic performance surrogate model thin film organic semiconductor deep convolutional neural networks manual exploration known domain insight mapping automated microstructure optimization datadriven approach microstructuresensitive design problems

Balaji Sesha Sarath Pokuri,Sambuddha Ghosal,Apurva Kokate,Soumik Sarkar,Baskar Ganapathysubramanian,.Interpretable deep learning for guided microstructure-property explorations in photovoltaics. 5 (1),.

Balaji Sesha Sarath Pokuri,Sambuddha Ghosal,Apurva Kokate,Soumik Sarkar,Baskar Ganapathysubramanian,"Interpretable deep learning for guided microstructure-property explorations in photovoltaics" 5

Balaji Sesha Sarath Pokuri,Sambuddha Ghosal,Apurva Kokate,Soumik Sarkar,Baskar Ganapathysubramanian,"Interpretable deep learning for guided microstructure-property explorations in photovoltaics"