Longitudinal Strain Engineering of Cu2–x S by the Juxtaposed Cu5FeS4 Phase in the Cu5FeS4/Cu2–x S/Cu5FeS4 Nanosandwich

Longitudinal Strain Engineering of Cu2–x S by the Juxtaposed Cu5FeS4 Phase in the Cu5FeS4/Cu2–x S/Cu5FeS4 Nanosandwich

Structurally well-defined heteronanoparticles have received great attention because their distinct structural features can be altered to achieve unprecedented properties. The cation exchange reaction, one of the most powerful techniques to synthesize heteronanoparticles, can tune the regiospecific c...

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Veröffentlicht in:Chemistry of materials 2019-11, Vol.31 (21), p.9070-9077
Hauptverfasser: Park, Jongsik, Lim, Sunghyun, Kwon, Taehyun, Jun, Minki, Oh, Aram, Baik, Hionsuck, Lee, Kwangyeol
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container_end_page 9077
container_issue 21
container_start_page 9070
container_title Chemistry of materials
container_volume 31
creator Park, Jongsik
Lim, Sunghyun
Kwon, Taehyun
Jun, Minki
Oh, Aram
Baik, Hionsuck
Lee, Kwangyeol
description Structurally well-defined heteronanoparticles have received great attention because their distinct structural features can be altered to achieve unprecedented properties. The cation exchange reaction, one of the most powerful techniques to synthesize heteronanoparticles, can tune the regiospecific composition of nanoparticles while maintaining the overall morphology of the template. Herein, we demonstrate that the nascent interface between the cation-exchanged region and the unchanged template can induce a significant tensile or compressive strain on the lattice of the template so that the cation exchange process at the interface can be greatly facilitated. The fate of the overall cation exchange reaction can be dictated by placing the initial cation exchange sites on the template regioselectively. Via a careful kinetic and thermodynamic control of the cation exchange, we could prepare two completely different nanostructures of Cu5FeS4/Cu2–x S/Cu5FeS4 nanosandwich and Cu5FeS4/Cu2–x S Janus nanoparticle. The synthetic concept described in this study could be further extended to the synthesis of various rationally designed multiphasic nanoparticles with exciting physicochemical properties.
doi_str_mv 10.1021/acs.chemmater.9b03342
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title Longitudinal Strain Engineering of Cu2–x S by the Juxtaposed Cu5FeS4 Phase in the Cu5FeS4/Cu2–x S/Cu5FeS4 Nanosandwich
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