Identificador persistente para citar o vincular este elemento: http://hdl.handle.net/10553/123136
Título: Stability of alkalinity in ocean alkalinity enhancement (OAE) approaches -consequences for durability of CO2 storage
Autores/as: Hartmann, Jens
Suitner, Niels
Lim, Carl
Schneider, Julieta
Marín Samper, Laura 
Arístegui Ruiz, Javier 
Renforth, Phil
Taucher, Jan
Riebesell, Ulf
Clasificación UNESCO: 251002 Oceanografía química
251001 Oceanografía biológica
Fecha de publicación: 2023
Publicación seriada: Biogeosciences 
Resumen: According to modelling studies, ocean alkalinity enhancement (OAE) is one of the proposed carbon dioxide removal (CDR) approaches with large potential, with the beneficial side effect of counteracting ocean acidification. The real-world application of OAE, however, remains unclear as most basic assumptions are untested. Before large-scale deployment can be considered, safe and sustainable procedures for the addition of alkalinity to seawater must be identified and governance established. One of the concerns is the stability of alkalinity when added to seawater. The surface ocean is already supersaturated with respect to calcite and aragonite, and an increase in total alkalinity (TA) together with a corresponding shift in carbonate chemistry towards higher carbonate ion concentrations would result in a further increase in supersaturation, and potentially to solid carbonate precipitation. Precipitation of carbonate minerals consumes alkalinity and increases dissolved CO2 in seawater, thereby reducing the efficiency of OAE for CO2 removal. In order to address the application of alkaline solution as well as fine particulate alkaline solids, a set of six experiments was performed using natural seawater with alkalinity of around 2400μmol kgsw-1. The application of CO2-equilibrated alkaline solution bears the lowest risk of losing alkalinity due to carbonate phase formation if added total alkalinity (δTA) is less than 2400μmol kgsw-1. The addition of reactive alkaline solids can cause a net loss of alkalinity if added δTA>600μmol kgsw-1 (e.g. for Mg(OH)2). Commercially available (ultrafine) Ca(OH)2 causes, in general, a net loss in TA for the tested amounts of TA addition, which has consequences for suggested use of slurries with alkaline solids supplied from ships. The rapid application of excessive amounts of Ca(OH)2, exceeding a threshold for alkalinity loss, resulted in a massive increase in TA (>20000μmol kgsw-1) at the cost of lower efficiency and resultant high pH values >9.5. Analysis of precipitates indicates formation of aragonite. However, unstable carbonate phases formed can partially redissolve, indicating that net loss of a fraction of alkalinity may not be permanent, which has important implications for real-world OAE application. Our results indicate that using an alkaline solution instead of reactive alkaline particles can avoid carbonate formation, unless alkalinity addition via solutions shifts the system beyond critical supersaturation levels. To avoid the loss of alkalinity and dissolved inorganic carbon (DIC) from seawater, the application of reactor techniques can be considered. These techniques produce an equilibrated solution from alkaline solids and CO2 prior to application. Differing behaviours of tested materials suggest that standardized engineered materials for OAE need to be developed to achieve safe and sustainable OAE with solids, if reactors technologies should be avoided.
URI: http://hdl.handle.net/10553/123136
ISSN: 1726-4170
DOI: 10.5194/bg-20-781-2023
Fuente: Biogeosciences [ISSN 1726-4170], v. 20 (4), p. 781–802, (2023)
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