Electron holography: Phase imaging with nanometer resolution

Martha McCartney; David Smith

doi:10.1146/annurev.matsci.37.052506.084219

Electron holography: Phase imaging with nanometer resolution

Martha McCartney, David Smith

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

178 Scopus citations

Abstract

Electron holography provides a unique phase-imaging approach for characterizing nanoscale electrostatic and magnetic fields. From the relative phase shifts of the electron wave that has passed through the sample, quantitative field measurements that can be related back to specific features of die object can be made. The basic theory and experimental geometry for the off-axis mode of electron holography are first presented. Representative studies over a wide range of materials are then described. Applications involving electrostatic fields include p-n junctions and dopant profiles, piezoelectric fields and ferroelectrics, and charged defects and boundaries. Applications involving magnetic materials include hard magnets, thin films, and nanostructures, both man-made and naturally occurring. Finally, prospects for future developments and applications are briefly discussed.

Original language	English (US)
Pages (from-to)	729-767
Number of pages	39
Journal	Annual Review of Materials Research
Volume	37
DOIs	https://doi.org/10.1146/annurev.matsci.37.052506.084219
State	Published - 2007

Keywords

Charged defects
Dopant profile
Electrostatic fields
Magnetic fields
Magnetization reversal
Off-axis electron holography
Patterned nanostructures
Piezoelectric fields
Remanent state

ASJC Scopus subject areas

General Materials Science

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10.1146/annurev.matsci.37.052506.084219

Cite this

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title = "Electron holography: Phase imaging with nanometer resolution",

abstract = "Electron holography provides a unique phase-imaging approach for characterizing nanoscale electrostatic and magnetic fields. From the relative phase shifts of the electron wave that has passed through the sample, quantitative field measurements that can be related back to specific features of die object can be made. The basic theory and experimental geometry for the off-axis mode of electron holography are first presented. Representative studies over a wide range of materials are then described. Applications involving electrostatic fields include p-n junctions and dopant profiles, piezoelectric fields and ferroelectrics, and charged defects and boundaries. Applications involving magnetic materials include hard magnets, thin films, and nanostructures, both man-made and naturally occurring. Finally, prospects for future developments and applications are briefly discussed.",

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T2 - Phase imaging with nanometer resolution

AU - McCartney, Martha

AU - Smith, David

PY - 2007

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AB - Electron holography provides a unique phase-imaging approach for characterizing nanoscale electrostatic and magnetic fields. From the relative phase shifts of the electron wave that has passed through the sample, quantitative field measurements that can be related back to specific features of die object can be made. The basic theory and experimental geometry for the off-axis mode of electron holography are first presented. Representative studies over a wide range of materials are then described. Applications involving electrostatic fields include p-n junctions and dopant profiles, piezoelectric fields and ferroelectrics, and charged defects and boundaries. Applications involving magnetic materials include hard magnets, thin films, and nanostructures, both man-made and naturally occurring. Finally, prospects for future developments and applications are briefly discussed.

KW - Charged defects

KW - Dopant profile

KW - Electrostatic fields

KW - Magnetic fields

KW - Magnetization reversal

KW - Off-axis electron holography

KW - Patterned nanostructures

KW - Piezoelectric fields

KW - Remanent state

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Electron holography: Phase imaging with nanometer resolution

Abstract

Keywords

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