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Diatom Frustule Silica Exhibits Superhydrophilicity and Superhemophilicity

Jeehee Lee, Haesung A. Lee, Haesung A. Lee, Mikyung Shin, Lih Jiin Juang, Christian J. Kastrup, Gyung Min Go, Haeshin Lee, Haeshin Lee

2020ACS Nano80 citationsDOI

Abstract

Special surface wettability attracts significant attention. In this study, dramatic differences in wettability are demonstrated for microparticles with the same chemical composition, SiO2. One is natural silica prepared from the diatom, Melosira nummuloides, and the other is synthetic silica. We found that surface properties of synthetic silica are hydro- and hemophobic. However, diatom frustule silica exhibits superhydrophilicity and even superhemophilicity. Interestingly, such superhydrophilicity of natural silica is not solely originated from nanoporous structures of diatoms but from the synergy of high-density silanol anions and the nanoarchitecture. Furthermore, the observation of superhemophilicity of natural silica is also an interesting finding, because not all superhydrophilic surfaces show superhemophilicity. We demonstrate that superhemowettability is a fundamental principle for developing micropowder-based hemostatic materials despite existing hemorrhaging studies using diatoms.

Topics & Concepts

SuperhydrophilicityFrustuleSilanolDiatomNanoporousWettingMaterials scienceChemical engineeringNanotechnologyChemistryOrganic chemistryComposite materialBiologyCatalysisBotanyEngineeringSurface Modification and SuperhydrophobicityCalcium Carbonate Crystallization and InhibitionPolymer Surface Interaction Studies