TY - GEN
T1 - Ferris-Wheel Magneto-Optic Kerr Effect and Optical Hall Effect Technique
AU - Am-Shalom, Nadav
AU - Rothschild, Amit
AU - Korcia, Maayan
AU - Bernstein, Nirel
AU - Kaplan, Daniel
AU - Holder, Tobias
AU - Yan, Binghai
AU - Rozhansky, Igor
AU - Capua, Amir
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - It is well known that the anomalous Hall effect displayed in ferromagnets is much stronger than the ordinary Hall effect. Similarly, the magneto-optical Kerr effect (MOKE) is orders of magnitude stronger than the optical Hall effect taking place in normal metals. Here, we present a MOKE technique that we term the 'Ferris' MOKE which is based on large-amplitude modulation of the externally applied magnetic field such that the sensitivity is enhanced by more than an order of magnitude. Consequently, the Ferris MOKE is found suitable for measurement of the optical Hall effect at visible light wavelengths where the effective electrical displacement is short. We derive a model that builds on the Lorentz-Drude formalism that accounts for the evanescent waves in the metal. By complementing the measurements with carrier density data extracted by DC Hall measurements, we show that the 'Ferris MOKE' measurement can reproduce previously reported effective masses that is indicative of the effective band curvature. Since the optical cycle is much shorter than the Drude mean free path, the technique may prove useful for probing intrinsic properties of the band structure and topological states of matter in non-magnetic materials.
AB - It is well known that the anomalous Hall effect displayed in ferromagnets is much stronger than the ordinary Hall effect. Similarly, the magneto-optical Kerr effect (MOKE) is orders of magnitude stronger than the optical Hall effect taking place in normal metals. Here, we present a MOKE technique that we term the 'Ferris' MOKE which is based on large-amplitude modulation of the externally applied magnetic field such that the sensitivity is enhanced by more than an order of magnitude. Consequently, the Ferris MOKE is found suitable for measurement of the optical Hall effect at visible light wavelengths where the effective electrical displacement is short. We derive a model that builds on the Lorentz-Drude formalism that accounts for the evanescent waves in the metal. By complementing the measurements with carrier density data extracted by DC Hall measurements, we show that the 'Ferris MOKE' measurement can reproduce previously reported effective masses that is indicative of the effective band curvature. Since the optical cycle is much shorter than the Drude mean free path, the technique may prove useful for probing intrinsic properties of the band structure and topological states of matter in non-magnetic materials.
KW - Hall effect
KW - Magneto-optic Kerr effect
KW - Optical Hall effect
UR - http://www.scopus.com/inward/record.url?scp=85198968114&partnerID=8YFLogxK
U2 - 10.1109/INTERMAGShortPapers61879.2024.10576866
DO - 10.1109/INTERMAGShortPapers61879.2024.10576866
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AN - SCOPUS:85198968114
T3 - 2024 IEEE International Magnetic Conference - Short Papers, INTERMAG Short Papers 2024 - Proceedings
BT - 2024 IEEE International Magnetic Conference - Short Papers, INTERMAG Short Papers 2024 - Proceedings
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2024 IEEE International Magnetic Conference - Short Papers, INTERMAG Short Papers 2024
Y2 - 5 May 2024 through 10 May 2024
ER -