Litcius/Paper detail

DecTree v1.0 – chemistry speedup in reactive transport simulations: purely data-driven and physics-based surrogates

Marco De Lucia, Michael Kühn

2021Geoscientific model development23 citationsDOIOpen Access PDF

Abstract

Abstract. The computational costs associated with coupled reactive transport simulations are mostly due to the chemical subsystem: replacing it with a pre-trained statistical surrogate is a promising strategy to achieve decisive speedups at the price of small accuracy losses and thus to extend the scale of problems which can be handled. We introduce a hierarchical coupling scheme in which “full-physics” equation-based geochemical simulations are partially replaced by surrogates. Errors in mass balance resulting from multivariate surrogate predictions effectively assess the accuracy of multivariate regressions at runtime: inaccurate surrogate predictions are rejected and the more expensive equation-based simulations are run instead. Gradient boosting regressors such as XGBoost, not requiring data standardization and being able to handle Tweedie distributions, proved to be a suitable emulator. Finally, we devise a surrogate approach based on geochemical knowledge, which overcomes the issue of robustness when encountering previously unseen data and which can serve as a basis for further development of hybrid physics–AI modelling.

Topics & Concepts

SpeedupRobustness (evolution)Computer scienceSurrogate modelMultivariate statisticsUncertainty quantificationBoosting (machine learning)Machine learningChemistryParallel computingBiochemistryGeneGroundwater flow and contamination studiesCO2 Sequestration and Geologic InteractionsGaussian Processes and Bayesian Inference