Magneto-optical properties of InSb for terahertz applications

Chochol, Jan; Postava, Kamil; Čada, Michael; Vanwolleghem, Mathias; Halagačka, Lukáš; Lampin, Jean‐François; Pištora, Jaromı́r

doi:10.1063/1.4968178

Cited by 63 publications

(50 citation statements)

References 27 publications

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“…We consider doped Indium Antimonide (InSb) slab which has been most widely studied in the context of coupled magneto-plasmon surface polaritons [41,42] and whose material permittivity dispersion has been wellcharacterized experimentally [43][44][45][46]. For the sake of completeness of our study, we extend the known permittivity model in [44][45][46] to the case of an arbitrarily oriented magnetic field in our geometry and obtain the semi-analytic form of permittivity given by e e w w w where m e =9.109 4×10 −31 kg is electron mass. Because of the antisymmetric (gyroelectric-type) permittivity tensor (e e = -T ) of InSb in presence of magnetic field, it is nonreciprocal and can lead to persistent features in its thermal near-field.…”

Section: Practical Example Of Insb Slabmentioning

confidence: 99%

“…Γ denotes the optical phonon damping constant while γ is the free-carrier damping constant. All parameters are obtained from[45,46] for InSb sample of doping density n=10 17 cm −3 . e = ¥ 15.7, ω L =3.62×10 13 rad s -1 , w =3.39 10 T 13 rad s -1 , ω p =3.14×10 13 rad s -1 , G =5.65 10 11 rad s -1 , γ=3.39×10 12 rad s -1 ,…”

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confidence: 99%

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Thermal spin photonics in the near-field of nonreciprocal media

Khandekar

Jacob

2019

New J. Phys.

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The interplay of spin angular momentum and thermal radiation is a frontier area of interest to nanophotonics as well as topological physics. Here, we show that a thick planar slab of a nonreciprocal material, despite being at thermal equilibrium with its environment, can exhibit nonzero photon spin angular momentum and nonzero radiative heat flux in its vicinity. We identify them as the persistent thermal photon spin and the persistent planar heat current respectively. With a practical example system, we reveal that the fundamental origin of these phenomena is connected to the spinmomentum locking of thermally excited evanescent waves. We also discover spin magnetic moment of surface polaritons that further clarifies these features. We then propose an imaging experiment based on Brownian motion that allows one to witness these surprising features by directly looking at them using a lab microscope. We further demonstrate the universal behavior of these near-field thermal radiation phenomena through a comprehensive analysis of gyroelectric, gyromagnetic and magneto-electric nonreciprocal materials. Together, these results expose a surprisingly little explored research area of thermal spin photonics with prospects for new avenues related to non-Hermitian topological photonics and radiative heat transport.

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Section: Practical Example Of Insb Slabmentioning

confidence: 99%

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confidence: 99%

Thermal spin photonics in the near-field of nonreciprocal media

Khandekar

Jacob

2019

New J. Phys.

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“…These effects combined explain the differences in obtained values. For measurement with higher doping levels see [32]. …”

Section: Magnetic Modulationmentioning

confidence: 99%

Plasmonic behavior of III-V semiconductors in far-infrared and terahertz range

Chochol

Postava

Čada

et al. 2017

J. Eur. Opt. Soc.-Rapid Publ.

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Background:In this article, III-V semiconductors are proposed as materials for far-infrared and terahertz plasmonic applications. We suggest criteria to estimate appropriate spectral range for each material including tuning by fine doping and magnetic field. Methods: Several single-crystal wafer samples (n,p-doped GaAs, n-doped InP, and n,p-doped and undoped InSb) are characterized using reflectivity measurement and their optical properties are described using the Drude-Lorentz model, including magneto-optical anisotropy. Results: The optical parameters of III-V semiconductors are presented. Moreover, strong magnetic modulation of permittivity was demonstrated on the undoped InSb crystal wafer in the terahertz spectral range. Description of this effect is presented and the obtained parameters are compared with a Hall effect measurement. Conclusion: Analyzing the phonon/free carrier contribution to the permittivity of the samples shows their possible use as plasmonic materials; the surface plasmon properties of semiconductors in the THz range resemble those of noble metals in the visible and near infrared range and their properties are tunable by either doping or magnetic field.

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“…Our separation process of different QMOKE contributions is stemming from 8-directional method [10], but we use a combination of just 4 directions and a sample rotation by 45 • as will be described later in the text. This approach allows us to isolate QMOKE spectra that stem mostly from individual MO parameters and thus subsequently determine spectral dependencies of G s = G 11 − G 12 and 2G 44 , denoting MO parameters quadratic in M [17,[38][39][40]. Therefore, we start our study on FM bcc Fe thin films grown on MgO(001) substrates to get a basic understanding of QMOKE spectroscopy for further studies of AFMs.…”

Section: Introductionmentioning

confidence: 99%

“…In the dc spectral range we can mention the well known anomalous Hall effect [41], being linear in M , and anisotropic magnetoresistance (AMR) [42] together with the planar Hall effect, both being quadratic in M . Recently, in the terahertz region, an MO effect of free carriers, the so-called optical Hall effect [43], has also received much attention [44]. From the x-ray family there is the well known x-ray magnetic circular (linear) dichroism and birefringence, being linear (quadratic) in M [45,46].…”

Section: Introductionmentioning

confidence: 99%

Quadratic magneto-optic Kerr effect spectroscopy of Fe epitaxial films on MgO(001) substrates

et al. 2019

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The magnetooptic Kerr effect (MOKE) is a well known and handy tool to characterize ferro-, ferri-and antiferromagnetic materials. Many of the MOKE techniques employ effects solely linear in magnetization M . Nevertheless, a higher-order term being proportional to M 2 and called quadratic MOKE (QMOKE) can additionally contribute to the experimental data. Here, we present detailed QMOKE spectroscopy measurements in the range of 0.8 -5.5 eV based on a modified 8-directional method applied on ferromagnetic bcc Fe thin films grown on MgO substrates. From the measured QMOKE spectra, two further complex spectra of the QMOKE parameters Gs and 2G44 are yielded. The difference between those two parameters, known as ∆G, denotes the strength of the QMOKE anisotropy. Those QMOKE parameters give rise to the QMOKE tensor G, fully describing the perturbation of the permittivity tensor in the second order in M for cubic crystal structures. We further present experimental measurements of ellipsometry and linear MOKE spectra, wherefrom permittivity in the zeroth and the first order in M are obtained, respectively. Finally, all those spectra are described by ab-initio calculations.

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Magneto-optical properties of InSb for terahertz applications

Cited by 63 publications

References 27 publications

Thermal spin photonics in the near-field of nonreciprocal media

Thermal spin photonics in the near-field of nonreciprocal media

Plasmonic behavior of III-V semiconductors in far-infrared and terahertz range

Quadratic magneto-optic Kerr effect spectroscopy of Fe epitaxial films on MgO(001) substrates

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