Mineral Surface Reactions at the Nanoscale

Reactions at mineral surfaces are central to all geochemical processes. As minerals comprise the rocks of the Earth, the processes occurring at the mineral–aqueous fluid interface control the evolution of the rocks and hence the structure of the crust of the Earth during processes such as metamorphi...

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מחבר ראשי: Putnis, Christine V.
פורמט: Online
שפה:אנגלית
יצא לאור: MDPI - Multidisciplinary Digital Publishing Institute 2021
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גישה מקוונת:33649
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author Putnis, Christine V.
author_browse Putnis, Christine V.
author_facet Putnis, Christine V.
author_sort Putnis, Christine V.
collection Directory of Open Access Books
description Reactions at mineral surfaces are central to all geochemical processes. As minerals comprise the rocks of the Earth, the processes occurring at the mineral–aqueous fluid interface control the evolution of the rocks and hence the structure of the crust of the Earth during processes such as metamorphism, metasomatism, and weathering. In recent years focus has been concentrated on mineral surface reactions made possible through the development of advanced analytical methods such as atomic force microscopy (AFM), advanced electron microscopies (SEM and TEM), phase shift interferometry, confocal Raman spectroscopy, and advanced synchrotron-based applications, to enable mineral surfaces to be imaged and analyzed at the nanoscale. Experiments are increasingly complemented by molecular simulations to confirm or predict the results of these studies. This has enabled new and exciting possibilities to elucidate the mechanisms that govern mineral–fluid reactions. In this Special Issue, “Mineral Surface Reactions at the Nanoscale”, we present 12 contributions that highlight the role and importance of mineral surfaces in varying fields of research.
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publisherStr MDPI - Multidisciplinary Digital Publishing Institute
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spelling doab-20.500.12854ir-535422024-04-09T11:41:37Z Mineral Surface Reactions at the Nanoscale Putnis, Christine V. QE1-996.5 Q1-390 metadynamics minerals n/a microstructure dissolution-reprecipitation stabilization albite mineral–water interface simulation krennerite mineralogy mineral replacement calcite pyrite dissolution-precipitation goethite recrystallization gold–(silver) tellurides isotopes non-classical nucleation calaverite interfacial precipitation toxic metals metasomatism adsorption amorphous pre-nucleation clusters surface dissolution hematite cyanide MOFs leaching Raman spectroscopy sodalite carbonation rate spectra retreat velocity additives liquid precursors bioaragonite brucite kinetics re-adsorption brushite polymorphs dissolution–precipitation hydrothermal experiments apatite ferrihydrite mesocrystals catalysts carbonic anhydrase XPS replacement reaction mineral growth carbon capture and storage interfaces citrate classical nucleation theory REEs phosphate wollastonite polarization microscopy natural porous gold sylvanite analcime calcium phosphate Fe atom exchange nepheline biomineralisation interface-coupled dissolution–reprecipitation hydrothermal method thema EDItEUR::R Earth Sciences, Geography, Environment, Planning Reactions at mineral surfaces are central to all geochemical processes. As minerals comprise the rocks of the Earth, the processes occurring at the mineral–aqueous fluid interface control the evolution of the rocks and hence the structure of the crust of the Earth during processes such as metamorphism, metasomatism, and weathering. In recent years focus has been concentrated on mineral surface reactions made possible through the development of advanced analytical methods such as atomic force microscopy (AFM), advanced electron microscopies (SEM and TEM), phase shift interferometry, confocal Raman spectroscopy, and advanced synchrotron-based applications, to enable mineral surfaces to be imaged and analyzed at the nanoscale. Experiments are increasingly complemented by molecular simulations to confirm or predict the results of these studies. This has enabled new and exciting possibilities to elucidate the mechanisms that govern mineral–fluid reactions. In this Special Issue, “Mineral Surface Reactions at the Nanoscale”, we present 12 contributions that highlight the role and importance of mineral surfaces in varying fields of research. 2021-02-11T19:44:14Z 2021-02-11T19:44:14Z 2019-06-26 08:44:06 2019 book 33649 9783038978961 9783038978978 https://directory.doabooks.org/handle/20.500.12854/53542 eng image/jpeg Attribution-NonCommercial-NoDerivatives 4.0 International https://mdpi.com/books/pdfview/book/1305 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-03897-897-8 10.3390/books978-3-03897-897-8 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783038978961 9783038978978 220 open access
spellingShingle QE1-996.5
Q1-390
metadynamics
minerals
n/a
microstructure
dissolution-reprecipitation
stabilization
albite
mineral–water interface
simulation
krennerite
mineralogy
mineral replacement
calcite
pyrite
dissolution-precipitation
goethite
recrystallization
gold–(silver) tellurides
isotopes
non-classical nucleation
calaverite
interfacial precipitation
toxic metals
metasomatism
adsorption
amorphous
pre-nucleation clusters
surface
dissolution
hematite
cyanide
MOFs
leaching
Raman spectroscopy
sodalite
carbonation
rate spectra
retreat velocity
additives
liquid precursors
bioaragonite
brucite
kinetics
re-adsorption
brushite
polymorphs
dissolution–precipitation
hydrothermal experiments
apatite
ferrihydrite
mesocrystals
catalysts
carbonic anhydrase
XPS
replacement reaction
mineral growth
carbon capture and storage
interfaces
citrate
classical nucleation theory
REEs
phosphate
wollastonite
polarization microscopy
natural porous gold
sylvanite
analcime
calcium phosphate
Fe atom exchange
nepheline
biomineralisation
interface-coupled dissolution–reprecipitation
hydrothermal method
thema EDItEUR::R Earth Sciences, Geography, Environment, Planning
Putnis, Christine V.
Mineral Surface Reactions at the Nanoscale
title Mineral Surface Reactions at the Nanoscale
title_full Mineral Surface Reactions at the Nanoscale
title_fullStr Mineral Surface Reactions at the Nanoscale
title_full_unstemmed Mineral Surface Reactions at the Nanoscale
title_short Mineral Surface Reactions at the Nanoscale
title_sort mineral surface reactions at the nanoscale
topic QE1-996.5
Q1-390
metadynamics
minerals
n/a
microstructure
dissolution-reprecipitation
stabilization
albite
mineral–water interface
simulation
krennerite
mineralogy
mineral replacement
calcite
pyrite
dissolution-precipitation
goethite
recrystallization
gold–(silver) tellurides
isotopes
non-classical nucleation
calaverite
interfacial precipitation
toxic metals
metasomatism
adsorption
amorphous
pre-nucleation clusters
surface
dissolution
hematite
cyanide
MOFs
leaching
Raman spectroscopy
sodalite
carbonation
rate spectra
retreat velocity
additives
liquid precursors
bioaragonite
brucite
kinetics
re-adsorption
brushite
polymorphs
dissolution–precipitation
hydrothermal experiments
apatite
ferrihydrite
mesocrystals
catalysts
carbonic anhydrase
XPS
replacement reaction
mineral growth
carbon capture and storage
interfaces
citrate
classical nucleation theory
REEs
phosphate
wollastonite
polarization microscopy
natural porous gold
sylvanite
analcime
calcium phosphate
Fe atom exchange
nepheline
biomineralisation
interface-coupled dissolution–reprecipitation
hydrothermal method
thema EDItEUR::R Earth Sciences, Geography, Environment, Planning
topic_facet QE1-996.5
Q1-390
metadynamics
minerals
n/a
microstructure
dissolution-reprecipitation
stabilization
albite
mineral–water interface
simulation
krennerite
mineralogy
mineral replacement
calcite
pyrite
dissolution-precipitation
goethite
recrystallization
gold–(silver) tellurides
isotopes
non-classical nucleation
calaverite
interfacial precipitation
toxic metals
metasomatism
adsorption
amorphous
pre-nucleation clusters
surface
dissolution
hematite
cyanide
MOFs
leaching
Raman spectroscopy
sodalite
carbonation
rate spectra
retreat velocity
additives
liquid precursors
bioaragonite
brucite
kinetics
re-adsorption
brushite
polymorphs
dissolution–precipitation
hydrothermal experiments
apatite
ferrihydrite
mesocrystals
catalysts
carbonic anhydrase
XPS
replacement reaction
mineral growth
carbon capture and storage
interfaces
citrate
classical nucleation theory
REEs
phosphate
wollastonite
polarization microscopy
natural porous gold
sylvanite
analcime
calcium phosphate
Fe atom exchange
nepheline
biomineralisation
interface-coupled dissolution–reprecipitation
hydrothermal method
thema EDItEUR::R Earth Sciences, Geography, Environment, Planning
url 33649
work_keys_str_mv AT putnischristinev mineralsurfacereactionsatthenanoscale