Embedding physics domain knowledge into a Bayesian network enables layer-by-layer process innovation for photovoltaics
Ren Z, Oviedo F, Thway M, Tian SIP, Wang Y, Xue H, Dario Perea J, Layurova M, Heumüller T, Birgersson E, Aberle AG, Brabec C, Stangl R, Li Q, Sun S, Lin F, Peters IM, Buonassisi T (2020)
Publication Type: Journal article
Publication year: 2020
Journal
Book Volume: 6
Journal Issue: 1
DOI: 10.1038/s41524-020-0277-x
Abstract
Process optimization of photovoltaic devices is a time-intensive, trial-and-error endeavor, which lacks full transparency of the underlying physics and relies on user-imposed constraints that may or may not lead to a global optimum. Herein, we demonstrate that embedding physics domain knowledge into a Bayesian network enables an optimization approach for gallium arsenide (GaAs) solar cells that identifies the root cause(s) of underperformance with layer-by-layer resolution and reveals alternative optimal process windows beyond traditional black-box optimization. Our Bayesian network approach links a key GaAs process variable (growth temperature) to material descriptors (bulk and interface properties, e.g., bulk lifetime, doping, and surface recombination) and device performance parameters (e.g., cell efficiency). For this purpose, we combine a Bayesian inference framework with a neural network surrogate device-physics model that is 100x faster than numerical solvers. With the trained surrogate model and only a small number of experimental samples, our approach reduces significantly the time-consuming intervention and characterization required by the experimentalist. As a demonstration of our method, in only five metal organic chemical vapor depositions, we identify a superior growth temperature profile for the window, bulk, and back surface field layer of a GaAs solar cell, without any secondary measurements, and demonstrate a 6.5% relative AM1.5G efficiency improvement above traditional grid search methods.
Authors with CRIS profile
Thomas Heumüller
Institute Materials for Electronics and Energy Technology (i-MEET)
Christoph Brabec
Institute Materials for Electronics and Energy Technology (i-MEET)
Involved external institutions
Singapore-MIT Alliance for Research and Technology (SMART)
Singapore (SG)
Massachusetts Institute of Technology (MIT)
United States (USA) (US)
National University of Singapore (NUS)
Singapore (SG)
Singapore (SG)
Massachusetts Institute of Technology (MIT)
United States (USA) (US)
National University of Singapore (NUS)
Singapore (SG)
How to cite
APA:
Ren, Z., Oviedo, F., Thway, M., Tian, S.I.P., Wang, Y., Xue, H.,... Buonassisi, T. (2020). Embedding physics domain knowledge into a Bayesian network enables layer-by-layer process innovation for photovoltaics. npj Computational Materials, 6(1). https://dx.doi.org/10.1038/s41524-020-0277-x
MLA:
Ren, Zekun, et al. "Embedding physics domain knowledge into a Bayesian network enables layer-by-layer process innovation for photovoltaics." npj Computational Materials 6.1 (2020).
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