Abstract The accelerating pace and expanding scope of materials discovery demand optimization frameworks that efficiently navigate vast, nonlinear design spaces while judiciously allocating limited evaluation resources. We present a cost-aware, batch Bayesian optimization scheme powered by deep Gaussian process (DGP) surro-gates and a heterotopic querying strategy. Our DGP surrogate, formed by stacking GP layers, models complex hierarchical relationships among high-dimensional compositional features and captures correlations acrossmultiple target properties, propagating uncertainty through successive layers. We integrate evaluation cost intoan upper-confidence-bound acquisition extension, which, together with heterotopic querying, proposes smallbatches of candidates in parallel, balancing exploration of under-characterized regions with exploitation ofhigh-mean, low-variance predictions across correlated properties. Applied to refractory high-entropy alloys for high-temperature applications, our framework converges to optimal formulations in fewer iterations with cost-aware queries than conventional GP-based BO, highlighting the value of deep, uncertainty-aware, cost-sensitive strategies in materials campaigns.
Hoseini et al. (Fri,) studied this question.
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