Direct Imaging of Nanoscale Dissolution of Dicalcium Phosphate Dihydrate by an Organic Ligand: Concentration Matters

Qin, Lihong; Zhang, Wenjun; Lu, Jianwei; Stack, Andrew G.; Wang, Lijun

doi:10.1021/es402748t

Cited by 41 publications

(67 citation statements)

References 68 publications

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“…Furthermore, calculated SI also predicts that low concentrations of citrate can promote the formation of strengite, tinticite, or cacoxenite formed on hematite or goethite [5] due to elevated SI (Tables S3 and S4). Organic acids in the soil solution typically range from 0.1 µM to 0.1 mM [5,25,26]. Our experiments also show that higher concentrations of citric acid retard Fe-P precipitation formation.…”

Section: Kinetics and Thermodynamics Of Coupled Dissolution-precipitation At The Iron Oxide-phosphate Solution Interfacesupporting

confidence: 54%

Interfacial Precipitation of Phosphate on Hematite and Goethite

et al. 2018

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Adsorption and subsequent precipitation of dissolved phosphates on iron oxides, such as hematite and goethite, is of considerable importance in predicting the bioavailability of phosphates. We used in situ atomic force microscopy (AFM) to image the kinetic processes of phosphate-bearing solutions interacting with hematite or goethite surfaces. The nucleation of nanoparticles (1.0-4.0 nm in height) of iron phosphate (Fe(III)-P) phases, possibly an amorphous phase at the initial stages, was observed during the dissolution of both hematite and goethite at the earliest crystallization stages. This was followed by a subsequent aggregation stage where larger particles and layered precipitates are formed under different pH values, ionic strengths, and organic additives. Kinetic analysis of the surface nucleation of Fe-P phases in 50 mM NH 4 H 2 PO 4 at pH 4.5 showed the nucleation rate was greater on goethite than hematite. Enhanced goethite and hematite dissolution in the presence of 10 mM AlCl 3 resulted in a rapid increase in Fe-P nucleation rates. A low concentration of citrate promoted the nucleation, whereas nucleation was inhibited at higher concentrations of citrate. By modeling using PHREEQC, calculated saturation indices (SI) showed that the three Fe(III)-P phases of cacoxenite, tinticite, and strengite may be supersaturated in the reacted solutions. Cacoxenite is predicted to be more thermodynamically favorable in all the phosphate solutions if equilibrium is reached with respect to hematite or goethite, although possibly only amorphous precipitates were observed at the earliest stages. These direct observations at the nanoscale may improve our understanding of phosphate immobilization in iron oxide-rich acid soils.

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Section: Kinetics and Thermodynamics Of Coupled Dissolution-precipitation At The Iron Oxide-phosphate Solution Interfacesupporting

confidence: 54%

Interfacial Precipitation of Phosphate on Hematite and Goethite

et al. 2018

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“…There are a number of proposed mechanisms, including enhancing chelation and complexation by inner/outer-sphere adsorbed species: 36−38 organic ligand anions bind in an inner-sphere, mononuclear, bidentate manner can dramatically enhance the dissolution kinetics of a variety of oxide minerals by polarizing bridging metal−oxygen bonds on mineral surfaces. 36 33 The introduction of low concentration OA for enhancing the step retreat rates along the [101] Cc steps could not be related to a thermodynamic driving force for dissolution because our AFM experiments are far away from equilibrium (as is the case for our solutions). 33 However, an alternative mechanism is that oxalate may alter the water molecular layer near the (010) face, effectively lowering the magnitude of the desolvation barrier, E K , by perturbations that displace water molecules, 39 or of the kinetic barrier, E b , 33,39 to removing Ca atoms along the [101] Cc steps to promote the dissolution.…”

Section: ■ Resultsmentioning

confidence: 99%

“…36 33 The introduction of low concentration OA for enhancing the step retreat rates along the [101] Cc steps could not be related to a thermodynamic driving force for dissolution because our AFM experiments are far away from equilibrium (as is the case for our solutions). 33 However, an alternative mechanism is that oxalate may alter the water molecular layer near the (010) face, effectively lowering the magnitude of the desolvation barrier, E K , by perturbations that displace water molecules, 39 or of the kinetic barrier, E b , 33,39 to removing Ca atoms along the [101] Cc steps to promote the dissolution. Net increase in the overall dissolution rates depends on retreat and deepening rates as well as the nucleation density of etch pits.…”

Section: ■ Resultsmentioning

confidence: 99%

“…41 Thus, we reasonably deduce that at the site of oxalate adsorption, especially on the [101] Cc steps, polarizing bridging Ca-oxygen bonds between surface Ca 2+ cation and the oxygen of the underlying HPO 4 2− anion in the DCPD surface layer by adsorbed oxalate, may generate greater ease of surface Ca 2+ detachment by all possible combinations of above processes/mechanisms at different OA concentrations. Furthermore, the specificity of the OA interaction with [101] Cc steps may be due to its bidentate structure containing two carboxylate groups, serving as double binding sites that allow for specific molecular recognition with the Ca atoms 33,42 or stereochemical interacting with step-edges on crystal surfaces and the step geometry that may allow double accommodations of carboxylate groups with the least amount of distortion. 43 For Our previous results have demonstrated that the local binding of negatively charged phosphate side chains to DCPD crystal faces rather than any secondary peptide structure to prevent step movement and increase interfacial/surface energies may be responsible for both the bulk and surface crystallization inhibition.…”

Section: ■ Resultsmentioning

confidence: 99%

“…33 Measurements were made on more than three crystals per solution composition to ensure reproducibility of the results, and each was imaged in different locations on the crystal (>3 points). All data (including the step retreat rates and the depths of etch pits) with their mean values ± standard deviation (SD) of three independent experiments are presented.…”

Section: ■ Experimental Sectionmentioning

confidence: 99%

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Direct Nanoscale Imaging of Calcium Oxalate Crystallization on Brushite Reveals the Mechanisms Underlying Stone Formation

Zhang

Wang

2015

Crystal Growth & Design

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A mixture of calcium oxalate and calcium phosphate is a source of chronic human disease, forming kidney stones. However, the mechanisms of pathological biomineralization and its modulation by natural inhibitors such as osteopontin (OPN) proteins are poorly defined at the nanoscale. Here, the in vitro formation of calcium oxalate monohydrate (COM) concretions having brushite nidi is observed using in situ atomic force microscopy (AFM) in a simulated acidic urinary milieu. We quantify the dissolution kinetics of the [101] Cc , [1̅ 00] Cc , and [101̅ ] Cc steps on the brushite (CaHPO 4 ·2H 2 O, DCPD) (010) surfaces by oxalate, two urinary constituents. In support of clinical observations, we further demonstrate the inhibitory effect of phosphorylated OPN peptides on the step retreat rates through step-specific interactions, this in turn regulating the kinetics of COM nucleation and aggregation at the expense of brushite crystals by means of the interfacial mineral replacement reactions. The definition of respective roles for DCPD and OPN peptides thereby offers general insights concerning the control of kidney stone formation and the mechanisms through which aberrant crystallization kinetics is inhibited.

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