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Extreme anti-reflection enhanced magneto-optic Kerr effect microscopy

Dongha Kim, Young‐Wan Oh, Jong Uk Kim, Soogil Lee, Arthur Baucour, Jonghwa Shin, Kab‐Jin Kim, Byong‐Guk Park, Min‐Kyo Seo

2020Nature Communications43 citationsDOIOpen Access PDF

Abstract

Magnetic and spintronic media have offered fundamental scientific subjects and technological applications. Magneto-optic Kerr effect (MOKE) microscopy provides the most accessible platform to study the dynamics of spins, magnetic quasi-particles, and domain walls. However, in the research of nanoscale spin textures and state-of-the-art spintronic devices, optical techniques are generally restricted by the extremely weak magneto-optical activity and diffraction limit. Highly sophisticated, expensive electron microscopy and scanning probe methods thus have come to the forefront. Here, we show that extreme anti-reflection (EAR) dramatically improves the performance and functionality of MOKE microscopy. For 1-nm-thin Co film, we demonstrate a Kerr amplitude as large as 20° and magnetic domain imaging visibility of 0.47. Especially, EAR-enhanced MOKE microscopy enables real-time detection and statistical analysis of sub-wavelength magnetic domain reversals. Furthermore, we exploit enhanced magneto-optic birefringence and demonstrate analyser-free MOKE microscopy. The EAR technique is promising for optical investigations and applications of nanomagnetic systems.

Topics & Concepts

Magneto-optic Kerr effectKerr effectMicroscopyMagnetic force microscopeSpintronicsMagnetic domainOpticsMaterials scienceBirefringenceOptoelectronicsNanotechnologyPhysicsCondensed matter physicsMagnetizationMagnetic fieldFerromagnetismQuantum mechanicsNonlinear systemMagneto-Optical Properties and ApplicationsMagnetic properties of thin filmsNear-Field Optical Microscopy
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