Experimental observations of dislocation core structures in gold and iridium

T. J. Balk; K. J. Hemker

doi:10.1016/S0921-5093(00)01622-1

Experimental observations of dislocation core structures in gold and iridium

T. J. Balk, K. J. Hemker

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Dislocation core structures are known to play an important role in determining the mechanical properties of metals and alloys. The ability to develop atomic level models of dislocation core structures that are based on first-principles or atomistic calculations has increased significantly in recent years, and in many ways these theoretical models have outpaced experimental observations. The HREM study outlined in this paper has been undertaken to provide an experimental benchmark for such models. In-situ TEM observations have been used to identify the presence of screw and 60° dislocations, and HREM images of these dislocations in both gold and iridium have been recorded. Computer-based image analyses have been employed to characterize subtle in-plane atomic level displacements, and direct comparisons with image simulations have been used to measure the separation distance between dissociated Shockley partial dislocations. The separations measured in this study have been found to be in good agreement with recently obtained theoretical predictions based on the first-principles calculations of Mryasov and colleagues.

Original language	English
Pages (from-to)	108-112
Number of pages	5
Journal	Materials Science and Engineering: A
Volume	309-310
DOIs	https://doi.org/10.1016/S0921-5093(00)01622-1
State	Published - Jul 15 2001

Bibliographical note

Funding Information:
Collaborations with Oleg Mryasov and Arthur Freeman, who performed the first-principles calculations of dislocation core structure, are greatly appreciated. Helpful advice for electropolishing was kindly provided by Peter Panfilov for iridium, and by Bernard Kestel for gold. Finally, the software package glot , written by Robin Schäublin, and the NCEM package for Digital Micrograph, written by Roar Kilaas and coworkers, were essential components of the quantification approach employed in this study. This work was supported by the US Air Force Office of Scientific Research, Grant No. F49620-98-1-0280. The Electron Microscopy Center at Johns Hopkins University has been generously supported by the W.M. Keck Foundation.

Keywords

Dislocation dissociation
Gold
High resolution electron microscopy
Iridium

ASJC Scopus subject areas

General Materials Science
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

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10.1016/S0921-5093(00)01622-1

Cite this

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title = "Experimental observations of dislocation core structures in gold and iridium",

abstract = "Dislocation core structures are known to play an important role in determining the mechanical properties of metals and alloys. The ability to develop atomic level models of dislocation core structures that are based on first-principles or atomistic calculations has increased significantly in recent years, and in many ways these theoretical models have outpaced experimental observations. The HREM study outlined in this paper has been undertaken to provide an experimental benchmark for such models. In-situ TEM observations have been used to identify the presence of screw and 60° dislocations, and HREM images of these dislocations in both gold and iridium have been recorded. Computer-based image analyses have been employed to characterize subtle in-plane atomic level displacements, and direct comparisons with image simulations have been used to measure the separation distance between dissociated Shockley partial dislocations. The separations measured in this study have been found to be in good agreement with recently obtained theoretical predictions based on the first-principles calculations of Mryasov and colleagues.",

keywords = "Dislocation dissociation, Gold, High resolution electron microscopy, Iridium",

author = "Balk, {T. J.} and Hemker, {K. J.}",

note = "Funding Information: Collaborations with Oleg Mryasov and Arthur Freeman, who performed the first-principles calculations of dislocation core structure, are greatly appreciated. Helpful advice for electropolishing was kindly provided by Peter Panfilov for iridium, and by Bernard Kestel for gold. Finally, the software package glot , written by Robin Sch{\"a}ublin, and the NCEM package for Digital Micrograph, written by Roar Kilaas and coworkers, were essential components of the quantification approach employed in this study. This work was supported by the US Air Force Office of Scientific Research, Grant No. F49620-98-1-0280. The Electron Microscopy Center at Johns Hopkins University has been generously supported by the W.M. Keck Foundation. ",

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AU - Hemker, K. J.

N1 - Funding Information: Collaborations with Oleg Mryasov and Arthur Freeman, who performed the first-principles calculations of dislocation core structure, are greatly appreciated. Helpful advice for electropolishing was kindly provided by Peter Panfilov for iridium, and by Bernard Kestel for gold. Finally, the software package glot , written by Robin Schäublin, and the NCEM package for Digital Micrograph, written by Roar Kilaas and coworkers, were essential components of the quantification approach employed in this study. This work was supported by the US Air Force Office of Scientific Research, Grant No. F49620-98-1-0280. The Electron Microscopy Center at Johns Hopkins University has been generously supported by the W.M. Keck Foundation.

PY - 2001/7/15

Y1 - 2001/7/15

N2 - Dislocation core structures are known to play an important role in determining the mechanical properties of metals and alloys. The ability to develop atomic level models of dislocation core structures that are based on first-principles or atomistic calculations has increased significantly in recent years, and in many ways these theoretical models have outpaced experimental observations. The HREM study outlined in this paper has been undertaken to provide an experimental benchmark for such models. In-situ TEM observations have been used to identify the presence of screw and 60° dislocations, and HREM images of these dislocations in both gold and iridium have been recorded. Computer-based image analyses have been employed to characterize subtle in-plane atomic level displacements, and direct comparisons with image simulations have been used to measure the separation distance between dissociated Shockley partial dislocations. The separations measured in this study have been found to be in good agreement with recently obtained theoretical predictions based on the first-principles calculations of Mryasov and colleagues.

AB - Dislocation core structures are known to play an important role in determining the mechanical properties of metals and alloys. The ability to develop atomic level models of dislocation core structures that are based on first-principles or atomistic calculations has increased significantly in recent years, and in many ways these theoretical models have outpaced experimental observations. The HREM study outlined in this paper has been undertaken to provide an experimental benchmark for such models. In-situ TEM observations have been used to identify the presence of screw and 60° dislocations, and HREM images of these dislocations in both gold and iridium have been recorded. Computer-based image analyses have been employed to characterize subtle in-plane atomic level displacements, and direct comparisons with image simulations have been used to measure the separation distance between dissociated Shockley partial dislocations. The separations measured in this study have been found to be in good agreement with recently obtained theoretical predictions based on the first-principles calculations of Mryasov and colleagues.

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Experimental observations of dislocation core structures in gold and iridium

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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