Nucleation in confinement generates long-range repulsion between rough calcite surfaces

Dziadkowiec, Joanna; Zareeipolgardani, Bahareh; Dysthe, Dag Kristian; Røyne, Anja

doi:10.1038/s41598-019-45163-6

Cited by 18 publications

(26 citation statements)

References 82 publications

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“…The interaction between two polycrystalline calcite surfaces and their surface reactivity in confinement has also been studied using an SFA, [322,323] and similar systems have been considered using modeling approaches. [324,325] Experiments were conducted using calcite surfaces glued to two crossed cylinder disks, where the calcite thin films were deposited on mica using atomic layer deposition.…”

Section: Surface Forces Apparatus (Sfa)mentioning

confidence: 99%

“…Solutions were saturated with CaCO 3 , and the influence of the additional electrolytes NaCl, CaCl 2 , and MgCl 2 was also explored. [ 322 ] Force curves were measured as a function of the surface separation, and repulsive forces were recorded in all cases. Despite the solution being saturated with respect to calcite, the calcite surfaces underwent minor dissolution, where this was attributed to the roughness of the films.…”

Section: Crystallization In Wedge Geometriesmentioning

confidence: 99%

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Crystallization in Confinement

2020

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Many crystallization processes of great importance, including frost heave, biomineralization, the synthesis of nanomaterials, and scale formation, occur in small volumes rather than bulk solution. Here, the influence of confinement on crystallization processes is described, drawing together information from fields as diverse as bioinspired mineralization, templating, pharmaceuticals, colloidal crystallization, and geochemistry. Experiments are principally conducted within confining systems that offer well‐defined environments, varying from droplets in microfluidic devices, to cylindrical pores in filtration membranes, to nanoporous glasses and carbon nanotubes. Dramatic effects are observed, including a stabilization of metastable polymorphs, a depression of freezing points, and the formation of crystals with preferred orientations, modified morphologies, and even structures not seen in bulk. Confinement is also shown to influence crystallization processes over length scales ranging from the atomic to hundreds of micrometers, and to originate from a wide range of mechanisms. The development of an enhanced understanding of the influence of confinement on crystal nucleation and growth will not only provide superior insight into crystallization processes in many real‐world environments, but will also enable this phenomenon to be used to control crystallization in applications including nanomaterial synthesis, heavy metal remediation, and the prevention of weathering.

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Section: Surface Forces Apparatus (Sfa)mentioning

confidence: 99%

Section: Crystallization In Wedge Geometriesmentioning

confidence: 99%

Crystallization in Confinement

2020

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“…Reactivity, recrystallization, and the resulting surface roughening of calcite surfaces often correlate with a much higher magnitude and range of repulsion that would be expected from the theoretical EDL contribution. 33 …”

Section: Introductionmentioning

confidence: 99%

“…Since the measurement of forces between the two calcite surfaces is experimentally challenging, these forces have been directly measured and distance-resolved only in few works using atomic force microscopy (AFM) and a surface force apparatus (SFA). − Repulsive or slightly adhesive forces act between the two calcite surfaces in calcite-saturated water and have been attributed to hydration repulsion that counteracts the attractive van der Waals (vdW) forces. Higher ionic strength (IS) due to the addition of NaCl or the presence of sulfate ions has been found to increase the adhesion, likely as an effect of EDL screening and attractive ion correlation forces.…”

Section: Introductionmentioning

confidence: 99%

Ca²⁺ Ions Decrease Adhesion between Two (104) Calcite Surfaces as Probed by Atomic Force Microscopy

Dziadkowiec

Ban

Javadi

et al. 2021

ACS Earth Space Chem.

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Solution composition-sensitive disjoining pressure acting between the mineral surfaces in fluid-filled granular rocks and materials controls their cohesion, facilitates the transport of dissolved species, and may sustain volume-expanding reactions leading to fracturing or pore sealing. Although calcite is one of the most abundant minerals in the Earth’s crust, there is still no complete understanding of how the most common inorganic ions affect the disjoining pressure (and thus the attractive or repulsive forces) operating between calcite surfaces. In this atomic force microscopy study, we measured adhesion acting between two cleaved (104) calcite surfaces in solutions containing low and high concentrations of Ca 2+ ions. We detected only low adhesion between calcite surfaces, which was weakly modulated by the varying Ca 2+ concentration. Our results show that the more hydrated calcium ions decrease the adhesion between calcite surfaces with respect to monovalent Na + at a given ionic strength, and thus Ca 2+ can sustain relatively thick water films between contacting calcite grains even at high overburden pressures. These findings suggest a possible loss of cohesion and continued progress of reaction-induced fracturing for weakly charged minerals in the presence of strongly hydrated ionic species.

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“…Also in nano-fluidics, stress-corrosion cracking, or geological dissolution processes, fluid-filled nano-channel geometries substantially alter ion diffusion (concentration gradient driven) and migration (field gradient driven) and the locally acting osmotic pressures, unlike in systems with limited spatial confinement [10][11][12][13] . Thus, experimental measurements of ion diffusion kinetics during a surface charging/discharging process in nano-cavities are essential to progress our understanding of charge regulation across all those systems.…”

Section: Introductionmentioning

confidence: 99%

Real-time visualization of metastable charge regulation pathways in molecularly confined slit geometries

Cheng¹,

Dziadkowiec²,

Wieser³

et al. 2021

Preprint

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Transport of ions in molecular-scale confined spaces is central to all aspects of life and technology: into a crack, it may break steel within days; through a membrane separator, it determines the efficiency of electrochemical energy conversion devices; or through lipid membranes, it steers neural communication. Yet, the direct observation of ion mobility and structuring in sub-nanometer confinement is experimentally challenging and, so far, solely accessible to molecular simulations. Here, we show quantitative, 3D molecularly-resolved ion transportation of aqueous ionic liquid and s-block metal ion solutions, confined to electrochemically-modulated, molecular-sized slits. Our analysis of atomically resolved solid/liquid interface unveils generic rules of how enthalpic ion-ion and ion-surface interactions and entropic confinement effects determine the charge regulation mechanism. Altering our general understanding, the confined charge regulation may proceed via fast, kinetically favoured, metastable pathways, followed by slow diffusive thermodynamic ion reorganization, which has important implications for all charge-regulated systems.

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Nucleation in confinement generates long-range repulsion between rough calcite surfaces

Cited by 18 publications

References 82 publications

Crystallization in Confinement

Crystallization in Confinement

Ca²⁺ Ions Decrease Adhesion between Two (104) Calcite Surfaces as Probed by Atomic Force Microscopy

Real-time visualization of metastable charge regulation pathways in molecularly confined slit geometries

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Nucleation in confinement generates long-range repulsion between rough calcite surfaces

Cited by 18 publications

References 82 publications

Crystallization in Confinement

Crystallization in Confinement

Ca2+ Ions Decrease Adhesion between Two (104) Calcite Surfaces as Probed by Atomic Force Microscopy

Real-time visualization of metastable charge regulation pathways in molecularly confined slit geometries

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Resources

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Ca²⁺ Ions Decrease Adhesion between Two (104) Calcite Surfaces as Probed by Atomic Force Microscopy