Pore-scale modeling of reactive transport in wellbore cement under CO2 storage conditions
Publication date
2012
Authors
Raoof, A.
Nick, H.M.
Wolterbeek, T.K.T.
Spiers, C.J.
Editors
Advisors
Supervisors
Document Type
Article
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(c) UU Universiteit Utrecht, 2012
Abstract
A modular pore-scale model is developed to assess the response of wellbore cement to geological storage
of CO2. Numerical formulations for modeling of solute transport are presented and a methodology for
coupling with geochemical processes is discussed, which includes: (1) advective and diffusive fluxes of
solutes within the pore space, (2) aqueous phase speciation, (3) mineral dissolution–precipitation kinetics,
and (4) the subsequent changes in pore space geometry. A Complex Pore Network Model (CPNM) is
used to discretize the continuum porous structure as a network of pore bodies and pore throats, both with
finite volumes. CPNM allows for a distribution of pore coordination numbers ranging between 1 and 26.
This topological property, together with a geometrical distribution of pore sizes, enables the microstructure
of porous media to be mimicked. For each pore element, transport of solute is calculated by solving
the governing mass balance equations. Chemical reaction of the fluid phase with the main reactive solid
components (portlandite and calcite) is incorporated through coupling with a geochemical reactive simulator.
Average values and properties are obtained by integration over a large number of pores. Using this
approach, we investigate how chemical reaction between water-bearing wellbore cement and supercritical
CO2 can create a distribution of porosity in a direction parallel to the CO2 concentration gradient and
transport path, at 50 ◦C. The dynamics of this process involve interaction between diffusion dominated
mass transport and the kinetics of dissolution and precipitation of portlandite and/or calcite. Simulation
of unconfined chemical degradation, in a fluid of constant composition, shows development of different
regions: (1) a zone adjacent to the inlet face, which is characterized by an increase in porosity due to
extensive dissolution, (2) a carbonation zone with decreased porosity, (3) the carbonation front which
made a thin layer with the lowest porosity due to calcium carbonate precipitation, and (4) dissolution
zone. These results are in agreement with laboratory observations under similar conditions. This provides
confidence that this pore-scale approach can ultimately be applied to model the progress of coupled CO2
transport and cement degradation at critical points along the length of cemented wellbore sections at
CO2 storage sites.
Keywords
Cement degradation, Reactive transport modeling, Wellbore integrity, CO2 storage, Porous medium, Dissolution–precipitation reactions, Pore network