Detail publikačního výsledku

Sub-10-nm quantification of spin and orbital magnetic moment across the metamagnetic phase transition in FeRh using EMCD

HAJDUČEK, J.; LECCESE, V.; RUSZ, J.; ARREGI URIBEETXEBARRIA, J.; SAPOZHNIK, A.; ŠTINDL, J.; BARANTANI, F.; CATTANEO, P.; ANDRIEUX, A.; CARBONE, F.; UHLÍŘ, V.; LAGRANGE, T.

Originální název

Sub-10-nm quantification of spin and orbital magnetic moment across the metamagnetic phase transition in FeRh using EMCD

Anglický název

Sub-10-nm quantification of spin and orbital magnetic moment across the metamagnetic phase transition in FeRh using EMCD

Druh

Článek WoS

Originální abstrakt

Electron magnetic circular dichroism (EMCD) in transmission electron microscopy (TEM) enables elementspecific measurement of spin and orbital magnetic moments, analogous to x-ray magnetic circular dichroism (XMCD). While the EMCD technique offers unmatched spatial resolution, its quantitative accuracy remains under scrutiny, particularly in beam-splitter geometries with convergent probes. Here, we systematically evaluate the limits of quantitative EMCD analysis using the first-order magnetostructural transition in the functional phase-change material FeRh as a tunable magnetic reference. Unlike previous EMCD studies primarily focused on elemental ferromagnets such as Fe, we demonstrate its applicability to a correlated material exhibiting coupled structural and magnetic order. We demonstrate that the extracted orbital-to-spin moment ratio (mL/mS) remains within the same order of magnitude as XMCD benchmarks, despite a systematic reduction in absolute value, for TEM probes down to approximately 6 nm, thereby establishing the validity range for reliable quantification. For nanometer-sized probes with higher convergence angles, we observe an enhanced mL/mS, which we attribute to a combination of instrumental factors and sensitivity to nanoscale heterogeneity within the probed volume. Our results confirm that EMCD provides quantitative agreement with macroscale techniques under suitable conditions, while uniquely enabling spatially confined measurements of local magnetic moments in functional magnetic materials, and allowing the study of interfacial, defect-mediated, or phase-separated magnetism that is inaccessible to photon-based methods.

Anglický abstrakt

Electron magnetic circular dichroism (EMCD) in transmission electron microscopy (TEM) enables elementspecific measurement of spin and orbital magnetic moments, analogous to x-ray magnetic circular dichroism (XMCD). While the EMCD technique offers unmatched spatial resolution, its quantitative accuracy remains under scrutiny, particularly in beam-splitter geometries with convergent probes. Here, we systematically evaluate the limits of quantitative EMCD analysis using the first-order magnetostructural transition in the functional phase-change material FeRh as a tunable magnetic reference. Unlike previous EMCD studies primarily focused on elemental ferromagnets such as Fe, we demonstrate its applicability to a correlated material exhibiting coupled structural and magnetic order. We demonstrate that the extracted orbital-to-spin moment ratio (mL/mS) remains within the same order of magnitude as XMCD benchmarks, despite a systematic reduction in absolute value, for TEM probes down to approximately 6 nm, thereby establishing the validity range for reliable quantification. For nanometer-sized probes with higher convergence angles, we observe an enhanced mL/mS, which we attribute to a combination of instrumental factors and sensitivity to nanoscale heterogeneity within the probed volume. Our results confirm that EMCD provides quantitative agreement with macroscale techniques under suitable conditions, while uniquely enabling spatially confined measurements of local magnetic moments in functional magnetic materials, and allowing the study of interfacial, defect-mediated, or phase-separated magnetism that is inaccessible to photon-based methods.

Klíčová slova

RAY CIRCULAR-DICHROISM; SUM-RULES; IRON; ENHANCEMENT; SCATTERING; ANISOTROPY; ALGORITHM; BEAMS; FILMS; CO

Klíčová slova v angličtině

RAY CIRCULAR-DICHROISM; SUM-RULES; IRON; ENHANCEMENT; SCATTERING; ANISOTROPY; ALGORITHM; BEAMS; FILMS; CO

Autoři

HAJDUČEK, J.; LECCESE, V.; RUSZ, J.; ARREGI URIBEETXEBARRIA, J.; SAPOZHNIK, A.; ŠTINDL, J.; BARANTANI, F.; CATTANEO, P.; ANDRIEUX, A.; CARBONE, F.; UHLÍŘ, V.; LAGRANGE, T.

Rok RIV

2026

Vydáno

26.01.2026

Nakladatel

American Physical Society

Periodikum

Physical Review Materials

Svazek

10

Číslo

1

Stát

Spojené státy americké

Strany od

1

Strany do

11

Strany počet

11

URL

Plný text v Digitální knihovně

BibTex

@article{BUT201394,
  author="Jan {Hajduček} and  {} and  {} and Jon Ander {Arregi Uribeetxebarria} and  {} and Jáchym {Štindl} and  {} and  {} and  {} and  {} and  {} and Vojtěch {Uhlíř} and  {}",
  title="Sub-10-nm quantification of spin and orbital magnetic moment across the metamagnetic phase transition in FeRh using EMCD",
  journal="Physical Review Materials",
  year="2026",
  volume="10",
  number="1",
  pages="11",
  doi="10.1103/m3vy-18hn",
  issn="2475-9953",
  url="https://journals.aps.org/prmaterials/abstract/10.1103/m3vy-18hn"
}