Genetically-Engineered Microdevices

Gas/solid displacement reactions have been examined as a means of altering the chemistry of bioclastic silica structures (e.g., the self-assembled microshells of diatoms, a type of aquatic algae) into other ceramic compositions. Complex-shaped silica microshells with nanoscale features were exposed...

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1. Verfasser:	Sandhage, Ken H
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Sprache:	eng
Schlagworte:	ALGAE CERAMIC MATERIALS Ceramics, Refractories and Glass CHEMICAL REACTIONS COMPOSITE MATERIALS DISPLACEMENT REACTIONS GENETIC ENGINEERING Inorganic Chemistry MAGNESIUM OXIDES MICRODEVICES SILICON SILICON DIOXIDE
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creator	Sandhage, Ken H
description	Gas/solid displacement reactions have been examined as a means of altering the chemistry of bioclastic silica structures (e.g., the self-assembled microshells of diatoms, a type of aquatic algae) into other ceramic compositions. Complex-shaped silica microshells with nanoscale features were exposed to Mg(g) at 9OO deg C. The silica microshells underwent the following net displacement reaction: 2Mg(g) + SiO2(s) yields 2MgO(s) + ?Si) (1) where ?Si! refers to silicon dissolved within a Mg-Si liquid. The Mg-Si liquid, which formed by the continued reaction of excess Mg(g) with reduced Si, was observed to sweat away from the solid MgO product of this reaction at 900 deg C to yield Si-free micro/nanostructures. The resulting MgO structures retained the 3-D shapes and fine features of the starting diatom microshells. This demonstration of shape-preserving chemical conversion opens the door to a wide variety of other chemical conversion reactions that we have begun to examine.
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Complex-shaped silica microshells with nanoscale features were exposed to Mg(g) at 9OO deg C. The silica microshells underwent the following net displacement reaction: 2Mg(g) + SiO2(s) yields 2MgO(s) + ?Si) (1) where ?Si! refers to silicon dissolved within a Mg-Si liquid. The Mg-Si liquid, which formed by the continued reaction of excess Mg(g) with reduced Si, was observed to sweat away from the solid MgO product of this reaction at 900 deg C to yield Si-free micro/nanostructures. The resulting MgO structures retained the 3-D shapes and fine features of the starting diatom microshells. 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subjects	ALGAE CERAMIC MATERIALS Ceramics, Refractories and Glass CHEMICAL REACTIONS COMPOSITE MATERIALS DISPLACEMENT REACTIONS GENETIC ENGINEERING Inorganic Chemistry MAGNESIUM OXIDES MICRODEVICES SILICON SILICON DIOXIDE
title	Genetically-Engineered Microdevices
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