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Polymer-Rich Dense Phase Can Concentrate Metastable Silica Precursors and Regulate Their Mineralization

Hang Zhai, Yuke Fan, Wenjun Zhang, Neta Varsano, Assaf Gal

2023ACS Biomaterials Science & Engineering12 citationsDOIOpen Access PDF

Abstract

Multistep mineralization processes are pivotal in the fabrication of functional materials and are often characterized by far from equilibrium conditions and high supersaturation. Interestingly, such 'nonclassical' mineralization pathways are widespread in biological systems, even though concentrating molecules well beyond their saturation level is incompatible with cellular homeostasis. Here, we show how polymer phase separation can facilitate bioinspired silica formation by passively concentrating the inorganic building blocks within the polymer dense phase. The high affinity of the dense phase to mobile silica precursors generates a diffusive flux against the concentration gradient, similar to dynamic equilibrium, and the resulting high supersaturation leads to precipitation of insoluble silica. Manipulating the chemistry of the dense phase allows to control the delicate interplay between polymer chemistry and silica precipitation. These results connect two phase transition phenomena, mineralization and coacervation, and offer a framework to achieve better control of mineral formation.

Topics & Concepts

CoacervateSupersaturationMineralization (soil science)PolymerMetastabilityPrecipitationChemical engineeringChemistryPhase (matter)Materials scienceNanotechnologyChromatographyOrganic chemistryEngineeringMeteorologyNitrogenPhysicsDiatoms and Algae ResearchCalcium Carbonate Crystallization and InhibitionPaleontology and Stratigraphy of Fossils
Polymer-Rich Dense Phase Can Concentrate Metastable Silica Precursors and Regulate Their Mineralization | Litcius