Atomic-Resolution Imaging of the Nanoscale Origin of Toughness in Rare-Earth Doped SiC

Aaron M. Kueck; Do Kyung Kim; Quentin M. Ramasse; L. C. De Jonghe; R. O. Ritchie

doi:10.1021/nl8017884

Atomic-Resolution Imaging of the Nanoscale Origin of Toughness in Rare-Earth Doped SiC

Aaron M. Kueck, Do Kyung Kim, Quentin M. Ramasse, L. C. De Jonghe, R. O. Ritchie^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

23 Citations (Scopus)

Abstract

Ultrahigh-resolution transmission electron microscopy and atomic-scale spectroscopy are used to investigate the origin of the toughness in rare-earth doped silicon carbide (RE-SiC) by examining the mechanistic nature of the intergranular cracking events which we find to occur precisely along the RE-decorated interface between the SiC grains and the nanoscale grain-boundary phase. We conclude that, for optimal toughness, the relative elastic modulus across the grain-boundary phase and the interfacial fracture toughness are the most critical material parameters; both can be altered with judicious choice of rare-earth elements.

Original language	English
Pages (from-to)	2935-2939
Journal	Nano Letters
Volume	8
Issue number	9
Online published	15 Aug 2008
DOIs	https://doi.org/10.1021/nl8017884
Publication status	Published - 10 Sept 2008
Externally published	Yes

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title = "Atomic-Resolution Imaging of the Nanoscale Origin of Toughness in Rare-Earth Doped SiC",

abstract = "Ultrahigh-resolution transmission electron microscopy and atomic-scale spectroscopy are used to investigate the origin of the toughness in rare-earth doped silicon carbide (RE-SiC) by examining the mechanistic nature of the intergranular cracking events which we find to occur precisely along the RE-decorated interface between the SiC grains and the nanoscale grain-boundary phase. We conclude that, for optimal toughness, the relative elastic modulus across the grain-boundary phase and the interfacial fracture toughness are the most critical material parameters; both can be altered with judicious choice of rare-earth elements.",

author = "Kueck, {Aaron M.} and Kim, {Do Kyung} and Ramasse, {Quentin M.} and {De Jonghe}, {L. C.} and Ritchie, {R. O.}",

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T1 - Atomic-Resolution Imaging of the Nanoscale Origin of Toughness in Rare-Earth Doped SiC

AU - Kueck, Aaron M.

AU - Kim, Do Kyung

AU - Ramasse, Quentin M.

AU - De Jonghe, L. C.

AU - Ritchie, R. O.

PY - 2008/9/10

Y1 - 2008/9/10

N2 - Ultrahigh-resolution transmission electron microscopy and atomic-scale spectroscopy are used to investigate the origin of the toughness in rare-earth doped silicon carbide (RE-SiC) by examining the mechanistic nature of the intergranular cracking events which we find to occur precisely along the RE-decorated interface between the SiC grains and the nanoscale grain-boundary phase. We conclude that, for optimal toughness, the relative elastic modulus across the grain-boundary phase and the interfacial fracture toughness are the most critical material parameters; both can be altered with judicious choice of rare-earth elements.

AB - Ultrahigh-resolution transmission electron microscopy and atomic-scale spectroscopy are used to investigate the origin of the toughness in rare-earth doped silicon carbide (RE-SiC) by examining the mechanistic nature of the intergranular cracking events which we find to occur precisely along the RE-decorated interface between the SiC grains and the nanoscale grain-boundary phase. We conclude that, for optimal toughness, the relative elastic modulus across the grain-boundary phase and the interfacial fracture toughness are the most critical material parameters; both can be altered with judicious choice of rare-earth elements.

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U2 - 10.1021/nl8017884

DO - 10.1021/nl8017884

M3 - RGC 21 - Publication in refereed journal

SN - 1530-6984

VL - 8

SP - 2935

EP - 2939

JO - Nano Letters

JF - Nano Letters

IS - 9

ER -

Atomic-Resolution Imaging of the Nanoscale Origin of Toughness in Rare-Earth Doped SiC

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