Thin films with precisely engineered nanostructure
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Posted On: 01/27/2017 12:30:37 PM
Thin films with precisely engineered nanostructures
Rohit Sarkar, Jagannathan Rajagopalan
(Submitted on 25 Jan 2017)
Synthesis of rationally designed nanostructured materials with optimized mechanical properties, e.g., high strength with considerable ductility, requires rigorous control of diverse microstructural parameters including the mean size, size dispersion and spatial distribution of grains. However, currently available synthesis techniques can seldom satisfy these requirements. Here, we report a new methodology to synthesize thin films with unprecedented microstructural control via systematic, in-situ seeding of nanocrystals into amorphous precursor films. When the amorphous films are subsequently crystallized by thermal annealing, the nanocrystals serve as preferential grain nucleation sites and control their microstructure. We demonstrate the capability of this approach by precisely tailoring the size, geometry and spatial distribution of nanostructured grains in structural (TiAl) as well as functional (TiNi) thin films. The approach, which is applicable to a broad class of metallic alloys and ceramics, enables explicit microstructural control of thin film materials for a wide spectrum of applications.
https://arxiv.org/abs/1701.07509
Rohit Sarkar, Jagannathan Rajagopalan
(Submitted on 25 Jan 2017)
Synthesis of rationally designed nanostructured materials with optimized mechanical properties, e.g., high strength with considerable ductility, requires rigorous control of diverse microstructural parameters including the mean size, size dispersion and spatial distribution of grains. However, currently available synthesis techniques can seldom satisfy these requirements. Here, we report a new methodology to synthesize thin films with unprecedented microstructural control via systematic, in-situ seeding of nanocrystals into amorphous precursor films. When the amorphous films are subsequently crystallized by thermal annealing, the nanocrystals serve as preferential grain nucleation sites and control their microstructure. We demonstrate the capability of this approach by precisely tailoring the size, geometry and spatial distribution of nanostructured grains in structural (TiAl) as well as functional (TiNi) thin films. The approach, which is applicable to a broad class of metallic alloys and ceramics, enables explicit microstructural control of thin film materials for a wide spectrum of applications.
https://arxiv.org/abs/1701.07509
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