Atomistic investigation of surface characteristics and electronic features at high-purity FeSi(110) presenting interfacial metallicity

Yang, Biao; Uphoff, Martin; Zhang, Yi‐Qi; Reichert, Joachim; Seitsonen, Ari P.; Bauer, Andreas; Pfleiderer, C.; Barth, Johannes V.

doi:10.1073/pnas.2021203118

Cited by 8 publications

(10 citation statements)

References 58 publications

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“…The observation that the normalized electrical resistance R ( T )/ R (120 K) below 19 K shows a dependence on the dimensions of the FeSi specimens along with the absence of any features in the specific heat at 19 K, indicated the presence of a CSS ( 1 ). Recent research employing scanning tunneling microscopy on high-quality FeSi single crystals supports the existence of surface conductivity of FeSi and further illustrates the similarity of its correlated electron properties to those of SmB 6 ( 42 ). Electrical transport, magnetization, and polarized neutron reflectometry measurements on FeSi nanofilms revealed a ferromagnetic metallic surface state closely related to the “Zak phase” of the bulk band topology of FeSi ( 43 ).…”

mentioning

confidence: 82%

Probing FeSi, a d -electron topological Kondo insulator candidate, with magnetic field, pressure, and microwaves

Breindel

Deng

Moir

et al. 2023

Proc. Natl. Acad. Sci. U.S.A.

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Recently, evidence for a conducting surface state (CSS) below 19 K was reported for the correlated d -electron small gap semiconductor FeSi. In the work reported herein, the CSS and the bulk phase of FeSi were probed via electrical resistivity ρ measurements as a function of temperature T , magnetic field B to 60 T, and pressure P to 7.6 GPa, and by means of a magnetic field-modulated microwave spectroscopy (MFMMS) technique. The properties of FeSi were also compared with those of the Kondo insulator SmB 6 to address the question of whether FeSi is a d -electron analogue of an f -electron Kondo insulator and, in addition, a “topological Kondo insulator” (TKI). The overall behavior of the magnetoresistance of FeSi at temperatures above and below the onset temperature T S = 19 K of the CSS is similar to that of SmB 6 . The two energy gaps, inferred from the ρ( T ) data in the semiconducting regime, increase with pressure up to about 7 GPa, followed by a drop which coincides with a sharp suppression of T S . Several studies of ρ( T ) under pressure on SmB 6 reveal behavior similar to that of FeSi in which the two energy gaps vanish at a critical pressure near the pressure at which T S vanishes, although the energy gaps in SmB 6 initially decrease with pressure, whereas in FeSi they increase with pressure. The MFMMS measurements showed a sharp feature at T S ≈ 19 K for FeSi, which could be due to ferromagnetic ordering of the CSS. However, no such feature was observed at T S ≈ 4.5 K for SmB 6 .

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mentioning

confidence: 82%

Probing FeSi, a d -electron topological Kondo insulator candidate, with magnetic field, pressure, and microwaves

Breindel

Deng

Moir

et al. 2023

Proc. Natl. Acad. Sci. U.S.A.

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“…Recently, the emergence of a high-mobility surface conduction channel at low temperatures was inferred from the electrical transport properties of a series of single crystals of FeSi prepared under systematic variation of the initial iron content using the optical floating-zone technique [19][20][21][22][23]. This observation was corroborated by means of measurements on thin needles grown from tin flux [24] as well as high-resolution tunneling spectroscopy that revealed two in-gap states in the low-temperature regime of the samples grown by the floating-zone technique [25]. The surface-to-bulk ratios of the charge carrier densities and mobilities observed in the transport properties compare quantitatively with values observed in topological insulators such as Bi 2 Te 3 [19,20,26].…”

Section: Introductionmentioning

confidence: 91%

Composition dependence of the specific heat of FeSi

Bürger

Bauer

Pfleiderer

2023

SciPost Phys. Proc.

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Recently, a high-mobility surface conduction channel and in-gap states were identified in the correlated small-gap semiconductor FeSi using electrical transport measurements and high-resolution tunneling spectroscopy. The mobility of the charge carriers in the surface channel is quantitatively reminiscent of topological insulators, but displays a lack of sensitivity to the presence of ferromagnetic impurities as studied by means of a series of single crystals with slightly different starting compositions. Here, we report measurements of the specific heat of these crystals. At low temperatures, a shallow maximum is observed in the specific heat divided by temperature. This maximum is suppressed under magnetic field, characteristic of a Schottky anomaly associated with magnetic impurities. In comparison, the height of this maximum decreases with increasing initial iron content.

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“…Recent discovery of spin–orbit coupled surface state of FeSi and its spintronic functionality showed an ideal example that may overcome the above technological issues. [ 19 ] While FeSi is a well‐known strongly correlated insulator, [ 20 ] its surface state was revealed to constitute metallic and ferromagnetic bands [ 19,21,22 ] confined to a thickness of 0.35 nm. In particular, as a consequence of its bulk‐band topology with nearly quantized Zak phase, [ 19,23–26 ] surface charges are asymmetrically distributed with respect to the surface atomic layer ( Figure a), causing out‐of‐plane potential gradient and hence Rashba‐type spin splitting of 35 meV at the Fermi energy.…”

Section: Introductionmentioning

confidence: 99%

“…Recent discovery of spin-orbit coupled surface state of FeSi and its spintronic functionality showed an ideal example that may overcome the above technological issues. [19] While FeSi is a well-known strongly correlated insulator, [20] its surface state was revealed to constitute metallic and ferromagnetic bands [19,21,22] Strongly spin-orbit coupled states at metal interfaces, topological insulators, and 2D materials enable efficient electric control of spin states, offering great potential for spintronics. However, there are still materials challenges to overcome, including the integration into advanced silicon electronics and the scarce resources of constituent heavy elements of those materials.…”

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confidence: 99%

A Noble‐Metal‐Free Spintronic System with Proximity‐Enhanced Ferromagnetic Topological Surface State of FeSi above Room Temperature

et al. 2022

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Strongly spin–orbit coupled states at metal interfaces, topological insulators, and 2D materials enable efficient electric control of spin states, offering great potential for spintronics. However, there are still materials challenges to overcome, including the integration into advanced silicon electronics and the scarce resources of constituent heavy elements of those materials. Through magneto‐transport measurements and first‐principles calculations, here robust spin–orbit coupling (SOC)‐induced properties of a ferromagnetic topological surface state in FeSi and their controllability via hybridization with adjacent materials are demonstrated. In comparison to the case of its naturally oxidized surface, the ferromagnetic transition temperature is greatly increased beyond room temperature and the effective SOC strength is almost doubled at the surface in proximity to a wide‐bandgap fluoride insulator. Those enhanced magnetic properties enable room‐temperature magnetization switching, being applicable to spin–orbit torque based spintronic devices. Realization of strong SOC in the noble‐metal‐free silicon‐based compound will accelerate spintronic applications.

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Atomistic investigation of surface characteristics and electronic features at high-purity FeSi(110) presenting interfacial metallicity

Cited by 8 publications

References 58 publications

Probing FeSi, a d -electron topological Kondo insulator candidate, with magnetic field, pressure, and microwaves

Probing FeSi, a d -electron topological Kondo insulator candidate, with magnetic field, pressure, and microwaves

Composition dependence of the specific heat of FeSi

A Noble‐Metal‐Free Spintronic System with Proximity‐Enhanced Ferromagnetic Topological Surface State of FeSi above Room Temperature

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