Back to Search Start Over

A community data mining approach for surface complexation database development

Authors :
(0000-0002-2426-6706) Zavarin, M.
(0000-0003-0304-399X) Chang, E.
(0000-0002-2140-6072) Wainwright, H.
Parham, N.
Kaukuntla, R.
(0000-0003-3497-4869) Zouabe, J.
(0000-0001-5886-7959) Deinhart, A.
(0000-0002-9577-0547) Genetti, V.
Shipman, S.
(0000-0002-6885-2619) Bok, F.
(0000-0001-5570-4177) Brendler, V.
(0000-0002-2426-6706) Zavarin, M.
(0000-0003-0304-399X) Chang, E.
(0000-0002-2140-6072) Wainwright, H.
Parham, N.
Kaukuntla, R.
(0000-0003-3497-4869) Zouabe, J.
(0000-0001-5886-7959) Deinhart, A.
(0000-0002-9577-0547) Genetti, V.
Shipman, S.
(0000-0002-6885-2619) Bok, F.
(0000-0001-5570-4177) Brendler, V.
Source :
Environmental Science & Technology 56(2022)4, 2827-2838
Publication Year :
2022

Abstract

This paper presents a comprehensive data-to-model workflow, including a findable, accessible, interoperable, reusable (FAIR) community sorption database (newly developed LLNL Surface Complexation/Ion Exchange (L-SCIE) database) along with a data fitting workflow to efficiently optimize surface complexation reaction constants with multiple surface complexation model (SCM) constructs. This workflow serves as a universal framework to mine, compile, and analyze large numbers of published sorption data as well as to estimate reaction constants for parameterizing reactive transport models. The framework includes (1) data digitization from published papers, (2) data unification including unit conversions, and (3) data-model integration and reaction constant estimation using geochemical software PHREEQC coupled with the universal parameter estimation code PEST. We demonstrate our approach using an analysis of U(VI) sorption to quartz based on a first L-SCIE implementation, concluding that a multisite SCM construct with carbonate surface species yielded the best fit to community data. Surface complexation reaction constants extracted from this approach captured all available sorption data available in the literature and provided insight into previously published reaction constants and surface complexation model constructs. The L-SCIE sorption database presented herein allows for automating this approach across a wide range of metals and minerals and implementing novel machine learning approaches to reactive transport in the future.

Details

Database :
OAIster
Journal :
Environmental Science & Technology 56(2022)4, 2827-2838
Notes :
application/pdf, English
Publication Type :
Electronic Resource
Accession number :
edsoai.on1415625629
Document Type :
Electronic Resource