Electron holography

Rafal E. Dunin-Borkowski; András Kovács; Takeshi Kasama; Martha R. McCartney; David J. Smith

doi:10.1007/978-3-030-00069-1_16

Electron holography

Rafal E. Dunin-Borkowski, András Kovács, Takeshi Kasama, Martha R. McCartney, David J. Smith

Physics

Research output: Chapter in Book/Report/Conference proceeding › Chapter

20 Scopus citations

Abstract

Electron holography is a powerful technique that allows the phase shift of a high-energy electron wave that has passed through a specimen in the transmission electron microscope to be measured directly. The phase shift can then be used to provide quantitative information about local variations in magnetic field and electrostatic potential both within and surrounding the specimen. This chapter begins with an outline of the experimental procedures and theoretical background that are needed to obtain phase information from electron holograms. It then presents recent examples of the application of electron holography to the characterization of magnetic domain structures and electrostatic fields in nanoscale materials and working devices, including arrangements of closely spaced nanocrystals, patterned elements and nanowires, and electrostatic fields in field emitters and doped semiconductors. The advantages of using digital approaches to record and analyze electron holograms are highlighted. Finally, high-resolution electron holography, alternative modes of electron holography and future prospects for the development of the technique are briefly outlined.

Original language	English (US)
Title of host publication	Springer Handbooks
Publisher	Springer
Pages	767-818
Number of pages	52
DOIs	https://doi.org/10.1007/978-3-030-00069-1_16
State	Published - 2019

Publication series

Name	Springer Handbooks
ISSN (Print)	2522-8692
ISSN (Electronic)	2522-8706

ASJC Scopus subject areas

General

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10.1007/978-3-030-00069-1_16

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@inbook{4ccd650fcb594064812e81c5b6984134,

title = "Electron holography",

abstract = "Electron holography is a powerful technique that allows the phase shift of a high-energy electron wave that has passed through a specimen in the transmission electron microscope to be measured directly. The phase shift can then be used to provide quantitative information about local variations in magnetic field and electrostatic potential both within and surrounding the specimen. This chapter begins with an outline of the experimental procedures and theoretical background that are needed to obtain phase information from electron holograms. It then presents recent examples of the application of electron holography to the characterization of magnetic domain structures and electrostatic fields in nanoscale materials and working devices, including arrangements of closely spaced nanocrystals, patterned elements and nanowires, and electrostatic fields in field emitters and doped semiconductors. The advantages of using digital approaches to record and analyze electron holograms are highlighted. Finally, high-resolution electron holography, alternative modes of electron holography and future prospects for the development of the technique are briefly outlined.",

author = "Dunin-Borkowski, {Rafal E.} and Andr{\'a}s Kov{\'a}cs and Takeshi Kasama and McCartney, {Martha R.} and Smith, {David J.}",

note = "Funding Information: Acknowledgments. The authors are grateful to T. Almeida, J. Barthel, M. Beleggia, S. Bl{\"u}gel, C.B. Boothroyd, T.J. Bromwich, R.F. Broom, P.R. Buseck, J. Caron, S. Chang, R.K.K. Chong, D. Cooper, P. Diehle, H. Du, C. Dwyer, R.B. Frankel, M. Farle, I. Farrer, J.M. Feinberg, P.E. Fischione, R.B. Frankel, K. Harada, R.J. Harrison, L.J. Heyder-man, M.J. H{\"y}tch, B.E. Kardynal, N. Kiselev, M. Kl{\"a}ui, J. Li, Z.-A. Li, J.C. Loudon, D. Meertens, P.A. Midg-ley, V. Migunov, A.R. Muxworthy, S.B. Newcomb, P. Parameswaran, A.K. Petford-Long, M. P{\'o}sfai, G. Pozzi, A. Putnis, D.A. Ritchie, A.C. Robins, C.A. Ross, M.R. Scheinfein, K. Shibata, E.T. Simpson, E. Snoeck, A.H. Tavabi, Y. Tokura, A. Tonomura, S.L. Tripp, A.C. Twitchett-Harrison, A. Wei, W. Williams, F. Winkler, S. Yazdi, F. Zheng and Y. Zhu for discussions and ongoing collaborations. This project has received funding from the European Union{\textquoteright}s Horizon 2020 research and innovation programme under grant agreement No. 823717-ESTEEM3. Publisher Copyright: {\textcopyright} Springer Nature Switzerland AG 2019.",

year = "2019",

doi = "10.1007/978-3-030-00069-1_16",

language = "English (US)",

series = "Springer Handbooks",

publisher = "Springer",

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T1 - Electron holography

AU - Dunin-Borkowski, Rafal E.

AU - Kovács, András

AU - Kasama, Takeshi

AU - McCartney, Martha R.

AU - Smith, David J.

N1 - Funding Information: Acknowledgments. The authors are grateful to T. Almeida, J. Barthel, M. Beleggia, S. Blügel, C.B. Boothroyd, T.J. Bromwich, R.F. Broom, P.R. Buseck, J. Caron, S. Chang, R.K.K. Chong, D. Cooper, P. Diehle, H. Du, C. Dwyer, R.B. Frankel, M. Farle, I. Farrer, J.M. Feinberg, P.E. Fischione, R.B. Frankel, K. Harada, R.J. Harrison, L.J. Heyder-man, M.J. Hÿtch, B.E. Kardynal, N. Kiselev, M. Kläui, J. Li, Z.-A. Li, J.C. Loudon, D. Meertens, P.A. Midg-ley, V. Migunov, A.R. Muxworthy, S.B. Newcomb, P. Parameswaran, A.K. Petford-Long, M. Pósfai, G. Pozzi, A. Putnis, D.A. Ritchie, A.C. Robins, C.A. Ross, M.R. Scheinfein, K. Shibata, E.T. Simpson, E. Snoeck, A.H. Tavabi, Y. Tokura, A. Tonomura, S.L. Tripp, A.C. Twitchett-Harrison, A. Wei, W. Williams, F. Winkler, S. Yazdi, F. Zheng and Y. Zhu for discussions and ongoing collaborations. This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No. 823717-ESTEEM3. Publisher Copyright: © Springer Nature Switzerland AG 2019.

PY - 2019

Y1 - 2019

N2 - Electron holography is a powerful technique that allows the phase shift of a high-energy electron wave that has passed through a specimen in the transmission electron microscope to be measured directly. The phase shift can then be used to provide quantitative information about local variations in magnetic field and electrostatic potential both within and surrounding the specimen. This chapter begins with an outline of the experimental procedures and theoretical background that are needed to obtain phase information from electron holograms. It then presents recent examples of the application of electron holography to the characterization of magnetic domain structures and electrostatic fields in nanoscale materials and working devices, including arrangements of closely spaced nanocrystals, patterned elements and nanowires, and electrostatic fields in field emitters and doped semiconductors. The advantages of using digital approaches to record and analyze electron holograms are highlighted. Finally, high-resolution electron holography, alternative modes of electron holography and future prospects for the development of the technique are briefly outlined.

AB - Electron holography is a powerful technique that allows the phase shift of a high-energy electron wave that has passed through a specimen in the transmission electron microscope to be measured directly. The phase shift can then be used to provide quantitative information about local variations in magnetic field and electrostatic potential both within and surrounding the specimen. This chapter begins with an outline of the experimental procedures and theoretical background that are needed to obtain phase information from electron holograms. It then presents recent examples of the application of electron holography to the characterization of magnetic domain structures and electrostatic fields in nanoscale materials and working devices, including arrangements of closely spaced nanocrystals, patterned elements and nanowires, and electrostatic fields in field emitters and doped semiconductors. The advantages of using digital approaches to record and analyze electron holograms are highlighted. Finally, high-resolution electron holography, alternative modes of electron holography and future prospects for the development of the technique are briefly outlined.

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PB - Springer

ER -

Electron holography

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