Precipitation of calcium carbonate and calcium phosphate under diffusion controlled mixing

•Double diffusion reactant mixing can control mineral precipitation in porous media.•Two chemical systems studied were calcium carbonate and calcium phosphate.•Complex coupling of physical and chemical processes controls precipitation outcomes.•Simulations involving reaction kinetics with porosity c...

Full description

Saved in:
Bibliographic Details
Published in:Applied geochemistry 2014-07, Vol.46, p.43-56
Main Authors: Gebrehiwet, Tsigabu, Guo, Luanjing, Fox, Don, Huang, Hai, Fujita, Yoshiko, Smith, Robert, Henriksen, James, Redden, George
Format: Article
Language:English
Subjects:
calcite
calcium carbonate
calcium phosphate
diffusion
double diffusion
Earth sciences
Earth, ocean, space
Engineering and environment geology. Geothermics
ENVIRONMENTAL SCIENCES/GLOBAL CLIMATE CHANGE STUDIES AND CLIMATE MITIGATION
Exact sciences and technology
Geochemistry
hydroxyapatite
mineral precipitation
mixing
Pollution, environment geology
porosity
solute transport
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Double diffusion reactant mixing can control mineral precipitation in porous media.•Two chemical systems studied were calcium carbonate and calcium phosphate.•Complex coupling of physical and chemical processes controls precipitation outcomes.•Simulations involving reaction kinetics with porosity changes requires high spatial resolution.•Properties of precipitation zones will affect potential engineering applications. Multi-component mineral precipitation in porous, subsurface environments is challenging to simulate or engineer when in situ reactant mixing is controlled by diffusion. In contrast to well-mixed systems, the conditions that favor mineral precipitation in porous media are distributed along chemical gradients, which evolve spatially due to concurrent mineral precipitation and modification of solute transport in the media. The resulting physical and chemical characteristics of a mixing/precipitation zone are a consequence of coupling between transport and chemical processes, and the distinctive properties of individual chemical systems. We examined the spatial distribution of precipitates formed in “double diffusion” columns for two chemical systems, calcium carbonate and calcium phosphate. Polyacrylamide hydrogel was used as a low permeability, high porosity medium to maximize diffusive mixing and minimize pressure- and density-driven flow between reactant solutions. In the calcium phosphate system, multiple, visually dense and narrow bands of precipitates were observed that were reminiscent of previously reported Liesegang patterns. In the calcium carbonate system, wider precipitation zones characterized by more sparse distributions of precipitates and a more open channel structure were observed. In both cases, formation of precipitates inhibited, but did not necessarily eliminate, continued transport and mixing of the reactants. A reactive transport model with fully implicit coupling between diffusion, chemical speciation and precipitation kinetics, but where explicit details of nucleation processes were neglected, was able to qualitatively simulate properties of the precipitation zones. The results help to illustrate how changes in the physical properties of a precipitation zone depend on coupling between diffusion-controlled reactant mixing and chemistry-specific details of precipitation kinetics.
ISSN:0883-2927
1872-9134
DOI:10.1016/j.apgeochem.2014.04.005