Orbital angular momentum resolved electron magnetic chiral dichroism

Rotunno, E.; Zanfrognini, M.; Frabboni, S.; Rusz, J.; Dunin Borkowski, R. E.; Karimi, E.; Grillo, V.

doi:10.1103/PhysRevB.100.224409

We propose to use the recently introduced orbital angular momentum spectrometer in a transmission electron microscope to perform electron magnetic chiral dichroism experiments, dispersing the inelastically scattered electrons from a magnetic material in both energy and angular momentum. The technique offers several advantages over previous formulations of electron magnetic chiral dichroism as it requires much simpler experimental conditions in terms of specimen orientation and thickness. A simulation algorithm, based on the multislice description of the beam propagation, is used to anticipate the advantages of the approach over current electron magnetic chiral dichroism implementations. Numerical calculations confirm an increased magnetic signal to noise ratio with in plane atomic resolution.

Orbital angular momentum resolved electron magnetic chiral dichroism / Rotunno, E.; Zanfrognini, M.; Frabboni, S.; Rusz, J.; Dunin Borkowski, R. E.; Karimi, E.; Grillo, V.. - In: PHYSICAL REVIEW. B. - ISSN 2469-9950. - 100:22(2019), pp. 1-11. [10.1103/PhysRevB.100.224409]

Orbital angular momentum resolved electron magnetic chiral dichroism

Rotunno E.;Zanfrognini M.;Frabboni S.;Rusz J.;Dunin Borkowski R. E.;Karimi E.;Grillo V.

2019

Abstract

We propose to use the recently introduced orbital angular momentum spectrometer in a transmission electron microscope to perform electron magnetic chiral dichroism experiments, dispersing the inelastically scattered electrons from a magnetic material in both energy and angular momentum. The technique offers several advantages over previous formulations of electron magnetic chiral dichroism as it requires much simpler experimental conditions in terms of specimen orientation and thickness. A simulation algorithm, based on the multislice description of the beam propagation, is used to anticipate the advantages of the approach over current electron magnetic chiral dichroism implementations. Numerical calculations confirm an increased magnetic signal to noise ratio with in plane atomic resolution.

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	Anno di pubblicazione
	
			2019
		
	Rivista
	
			PHYSICAL REVIEW. B
		
	N° del Volume
	
			100
		
	Fascicolo
	
			22
		
	Pagina iniziale
	
			1
		
	Pagina finale
	
			11
		
	Codice DOI
	
			https://dx.doi.org/10.1103/PhysRevB.100.224409
		
	Codice WoS
	
			WOS:000501542400004
		
	Codice Scopus
	
			2-s2.0-85076552620
		
	Citazione
	
			Orbital angular momentum resolved electron magnetic chiral dichroism / Rotunno, E.; Zanfrognini, M.; Frabboni, S.; Rusz, J.; Dunin Borkowski, R. E.; Karimi, E.; Grillo, V.. - In: PHYSICAL REVIEW. B. - ISSN 2469-9950. - 100:22(2019), pp. 1-11. [10.1103/PhysRevB.100.224409]
		
	Tutti gli autori
	
			Rotunno, E.; Zanfrognini, M.; Frabboni, S.; Rusz, J.; Dunin Borkowski, R. E.; Karimi, E.; Grillo, V.
		
	Tipologia
	
			Articolo su rivista

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