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1. Temperature Dependence of Relativistic Valence Band Splitting Induced by an Altermagnetic Phase Transition

Author

Hajlaoui, M., D'Souza, S. W., Šmejkal, L., Kriegner, D., Krizman, G., Zakusylo, T., Olszowska, N., Caha, O., Michalička, J., Marmodoro, A., Výborný, K., Ernst, A., Cinchetti, M., Minar, J., Jungwirth, T., and Springholz, G.

Subjects
Condensed Matter - Materials Science
Abstract

Altermagnetic (AM) materials exhibit non-relativistic, momentum-dependent spin-split states, ushering in new opportunities for spin electronic devices. While the characteristics of spin-splitting have been documented within the framework of the non-relativistic spin group symmetry, there has been limited exploration of the inclusion of relativistic symmetry and its impact on the emergence of a novel spin-splitting in the band structure. This study delves into the intricate relativistic electronic structure of an AM material, alpha-MnTe. Employing temperature-dependent angle-resolved photoelectron spectroscopy across the AM phase transition, we elucidate the emergence of a relativistic valence band splitting concurrent with the establishment of magnetic order. This discovery is validated through disordered local moment calculations, modeling the influence of magnetic order on the electronic structure and confirming the magnetic origin of the observed splitting. The temperature-dependent splitting is ascribed to the advent of relativistic spin-splitting resulting from the strengthening of AM order in alpha-MnTe as the temperature decreases. This sheds light on a previously unexplored facet of this intriguing material.

Published
2024
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2. Valley-Polarized quantum Hall phase in a strain-controlled Dirac system

Author

Krizman, G., Bermejo-Ortiz, J., Zakusylo, T., Hajlaoui, M., Takashiro, T., Rosmus, M., Olszowska, N., Kolodziej, J. J., Bauer, G., Guldner, Y., Springholz, G., and de Vaulchier, L. -A.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Other Condensed Matter
Abstract

In multivalley systems, the valley pseudospin offers rich physics going from encoding of information by its polarization (valleytronics), to exploring novel phases of matter when its degeneracy is changed. Here, by strain engineering, we reveal fully valley-polarized quantum Hall (QH) phases in the Pb1-xSnxSe Dirac system. Remarkably, when the valley energy splitting exceeds the fundamental band gap, we observe a bipolar QH phase, heralded by the coexistence of hole and electron chiral edge states at distinct valleys in the same quantum well. This suggests that spatially overlaid counter-propagating chiral edge states emerging at different valleys do not interfere with each other.

Published
2024
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3. Observation of Weyl and Dirac fermions at smooth topological Volkov-Pankratov heterojunctions

Author

Bermejo-Ortiz, J., Krizman, G., Jakiela, R., Khosravizadeh, Z., Hajlaoui, M., Bauer, G., Springholz, G., de Vaulchier, L. A., and Guldner, Y.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Other Condensed Matter
Abstract

Weyl and Dirac relativistic fermions are ubiquitous in topological matter. Their relativistic character enables high energy physics phenomena like the chiral anomaly to occur in solid state, which allows to experimentally probe and explore fundamental relativistic theories. Here we show that on smooth interfaces between a trivial and a topological material, massless Weyl and massive Dirac fermions intrinsically coexist. The emergence of the latter, known as Volkov-Pankratov states, is directly revealed by magneto-optical spectroscopy, evidencing that their energy spectrum is perfectly controlled by the smoothness of topological interface. Simultaneously, we reveal the optical absorption of the zero-energy chiral Weyl state, whose wavefunction is drastically transformed when the topological interface is smooth. Artificial engineering of the topology profile thus provides a novel textbook system to explore the rich relativistic energy spectra in condensed matter heterostructures., Comment: 21 pages 10 figures

Published
2022
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4. Miniband engineering and topological phase transitions in topological - normal insulator superlattices

Author

Krizman, G., Assaf, B. A., Bauer, G., Springholz, G., de Vaulchier, L. A., and Guldner, Y.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Periodic stacking of topologically trivial and non-trivial layers with opposite symmetry of the valence and conduction bands induces topological interface states that, in the strong coupling limit, hybridize both across the topological and normal insulator layers. Using band structure engineering, such superlattices can be effectively realized using the IV-VI lead tin chalcogenides. This leads to emergent minibands with a tunable topology as demonstrated both by theory and experiments. The topological minibands are proven by magneto-optical spectroscopy, revealing Landau level transitions both at the center and edges of the artificial superlattice mini Brillouin zone. Their topological character is identified by the topological phase transitions within the minibands observed as a function of temperature. The critical temperature of this transition as well as the miniband gap and miniband width can be precisely controlled by the layer thicknesses and compositions. This witnesses the generation of a new fully tunable quasi-3D topological state that provides a template for realization of magnetic Weyl semimetals and other strongly interacting topological phases., Comment: 21 pages, 8 figures

Published
2021
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5. Determination of the crystal field splitting energy in Cd3As2 using magnetooptics

Author

Krizman, G., Schumann, T., Tchoumakov, S., Assaf, B. A., Stemmer, S., de Vaulchier, L. A., and Guldner, Y.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Symmetry considerations are of extreme importance to the topological properties of crystals. A crystal field splitting {\delta} yields Dirac nodes near the Brillouin zone center in Cd3As2, but its value has yet to be determined with precision. We study the band structure of Cd3As2 using magnetooptical infrared spectroscopy measurements on epilayers with low carrier density grown by molecular beam epitaxy. By combining angular dependent cyclotron resonance with Landau level spectroscopy measurements in the Faraday geometry, we determine that {\delta} is positive and equal to 15+/-5 meV in Cd3As2. Our results lead to a more accurate knowledge of the details of the band structure of this Dirac semimetal such as the position its Dirac nodes in momentum space and their splitting into Weyl nodes under a magnetic field., Comment: Accepted Phys Rev B

Published
2019
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6. Dirac parameters and topological phase diagram of Pb1-xSnxSe from magneto-spectroscopy

Author

Krizman, G., Assaf, B. A., Phuphachong, T., Bauer, G., Springholz, G., de Vaulchier, L. A., and Guldner, Y.

Subjects
Condensed Matter - Materials Science
Abstract

Pb1-xSnxSe hosts 3D massive Dirac fermions across the entire composition range for which the crystal structure is cubic. In this work, we present a comprehensive experimental mapping of the 3D band structure parameters of Pb1-xSnxSe as a function of composition and temperature. We cover a parameter space spanning the band inversion that yields its topological crystalline insulator phase. A non-closure of the energy gap is evidenced in the vicinity of this phase transition. Using magnetooptical Landau level spectroscopy, we determine the energy gap, Dirac velocity, anisotropy factor and topological character of Pb1-xSnxSe epilayers grown by molecular beam epitaxy on BaF2 (111). Our results are evidence that Pb1-xSnxSe is a model system to study topological phases and the nature of the phase transition., Comment: Submitted

Published
2018
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7. Avoided level crossing at the magnetic field induced topological phase transition due to spin-orbital mixing

Author

Krizman, G., Assaf, B. A., Orlita, M., Phuphachong, T., Bauer, G., Springholz, G., Bastard, G., Ferreira, R., de Vaulchier, L. A., and Guldner, Y.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In 3D topological insulators, an effective closure of the bulk energy gap with increasing magnetic field expected at a critical point can yield a band crossing at a gapless Dirac node. Using high-field magnetooptical Landau level spectroscopy on the topological crystalline insulator Pb1-xSnxSe, we demonstrate that such a gap closure does not occur, and an avoided crossing is observed as the magnetic field is swept through the critical field. We attribute this anticrossing to orbital parity and spin mixing of the N=0 levels. Concurrently, we observe no gap closure at the topological phase transition versus temperature suggesting that the anticrossing is a generic property of topological phase transitions., Comment: submitted

Published
2018
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8. Tunable Dirac interface states in topological superlattices

Author

Krizman, G., Assaf, B. A., Phuphachong, T., Bauer, G., Springholz, G., Bastard, G., Ferreira, R., de Vaulchier, L. A., and Guldner, Y.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Relativistic Dirac fermions are ubiquitous in condensed matter physics. Their mass is proportional to the material energy gap and the ability to control and tune the mass has become an essential tool to engineer quantum phenomena that mimic high energy particles and provide novel device functionalities. In topological insulator thin films, new states of matter can be generated by hybridizing the massless Dirac states that occur at material surfaces. In this work, we experimentally and theoretically introduce a platform where this hybridization can be continuously tuned: the Pb1-xSnxSe topological superlattice. In this system, topological Dirac states occur at the interfaces between a topological crystalline insulator Pb1-xSnxSe and a trivial insulator, realized in the form of topological quantum wells (TQW) epitaxially stacked on top of each other. Using magnetooptical transmission spectroscopy on high quality MBE grown Pb1-xSnxSe superlattices, we show that the penetration depth of the TQW interface states and therefore their Dirac mass is continuously tunable with temperature. This presents a new pathway to engineer the Dirac mass of topological systems and paves the way towards the realization of emergent quantum states of matter using Pb1-xSnxSe topological superlattices., Comment: See journal for supplementary material access

Published
2018
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9. Valley-Polarized Quantum Hall Phase in a Strain-Controlled Dirac System

Author

Krizman, G., primary, Bermejo-Ortiz, J., additional, Zakusylo, T., additional, Hajlaoui, M., additional, Takashiro, T., additional, Rosmus, M., additional, Olszowska, N., additional, Kołodziej, J. J., additional, Bauer, G., additional, Guldner, Y., additional, Springholz, G., additional, and de Vaulchier, L.-A., additional

Published
2024
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10. Magneto-spectroscopy investigation of InAs/InAsSb superlattices for midwave infrared detection.

Author

Krizman, G., Carosella, F., Bermejo-Ortiz, J., Philippe, A., Rodriguez, J. B., Perez, J.-P., Christol, P., de Vaulchier, L.-A., and Guldner, Y.

Subjects
*SUPERLATTICES, *LANDAU levels, *ELECTRONIC equipment, *PHOTODETECTORS, *MAGNETOOPTICS, *LIGHT absorbance
Abstract

Raising the operating temperature of the midwave infrared (MWIR) cameras up to 150 K without penalizing the performances of the photodetectors is one of the main challenges of the domain. Moreover, extending the range of detection up to 5 μ m brings many advantages. Ga-free InAs/InAsSb superlattice based devices have been recently fabricated and they showed the first realization of these objectives. However, the band parameters (band offsets, effect of strain, effective mass) of this system have not been determined accurately, thus limiting the understanding and the prediction of the electronic properties of the devices. In this work, we determined the relevant parameters via magnetoabsorption measurements performed on dedicated superlattices. Interband magneto-optical transitions lead to an accurate mapping of the Landau levels. The Landau level energies have been calculated using an 8-band k ⋅ p model, and the comparison with the experimental data provided a clear description of the type 2 superlattice miniband structure at 4.2 and 150 K, as well as its MWIR absorbance. [ABSTRACT FROM AUTHOR]

Published
2021
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14. Fermi level tuning and band alignment in Mn-doped InAs/GaSb

Author

Riney, L., primary, Bermejo-Ortiz, J., additional, Krizman, G., additional, Bac, S.-K., additional, Wang, J., additional, Zhukovskyi, M., additional, Orlova, T., additional, de Vaulchier, L. A., additional, Guldner, Y., additional, Winkler, R., additional, Furdyna, J. K., additional, Liu, X., additional, and Assaf, B. A., additional

Published
2022
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17. Dirac parameters and topological phase diagram of Pb(1−x)Sn(x)Se from magnetospectroscopy

Author

Krizman, G., Assaf, Badih, Phuphachong, T., Bauer, G., Springholz, G., de Vaulchier, L.A., Guldner, Y., Laboratoire Pierre Aigrain (LPA), Université Pierre et Marie Curie - Paris 6 (UPMC)-Université Paris Diderot - Paris 7 (UPD7)-Fédération de recherche du Département de physique de l'Ecole Normale Supérieure - ENS Paris (FRDPENS), École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Fédération de recherche du Département de physique de l'Ecole Normale Supérieure - ENS Paris (FRDPENS), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS), Department of Physics [Notre Dame], University of Notre Dame [Indiana] (UND), Institut für Halbleiter und Festkörperphysik, and Johannes Kepler Universität

Subjects
[PHYS.COND.CM-MS]Physics [physics]/Condensed Matter [cond-mat]/Materials Science [cond-mat.mtrl-sci], ComputingMilieux_MISCELLANEOUS
Abstract

International audience

Published
2018
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25. A Novel Ferroelectric Rashba Semiconductor.

Author

Krizman G, Zakusylo T, Sajeev L, Hajlaoui M, Takashiro T, Rosmus M, Olszowska N, Kołodziej JJ, Bauer G, Caha O, and Springholz G

Abstract

Fast, reversible, and low-power manipulation of the spin texture is crucial for next generation spintronic devices like non-volatile bipolar memories, switchable spin current injectors or spin field effect transistors. Ferroelectric Rashba semiconductors (FERSC) are the ideal class of materials for the realization of such devices. Their ferroelectric character enables an electronic control of the Rashba-type spin texture by means of the reversible and switchable polarization. Yet, only very few materials are established to belong to this class of multifunctional materials. Here, Pb 1- x Ge x Te is unraveled as a novel FERSC system down to nanoscale. The ferroelectric phase transition and concomitant lattice distortion are demonstrated by temperature dependent X-ray diffraction, and their effect on electronic properties are measured by angle-resolved photoemission spectroscopy. In few nanometer-thick epitaxial heterostructures, a large Rashba spin-splitting is exhibiting a wide tuning range as a function of temperature and Ge content. This work defines Pb 1- x Ge x Te as a high-potential FERSC system for spintronic applications., (© 2023 The Authors. Advanced Materials published by Wiley‐VCH GmbH.)

Published
2024
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26. Persistence of Structural Distortion and Bulk Band Rashba Splitting in SnTe above Its Ferroelectric Critical Temperature.

Author

Chassot F, Pulkkinen A, Kremer G, Zakusylo T, Krizman G, Hajlaoui M, Dil JH, Krempaský J, Minár J, Springholz G, and Monney C

Abstract

The ferroelectric semiconductor α-SnTe has been regarded as a topological crystalline insulator, and the dispersion of its surface states has been intensively measured with angle-resolved photoemission spectroscopy (ARPES) over the past decade. However, much less attention has been given to the impact of the ferroelectric transition on its electronic structure, and in particular on its bulk states. Here, we investigate the low-energy electronic structure of α-SnTe with ARPES and follow the evolution of the bulk-state Rashba splitting as a function of temperature, across its ferroelectric critical temperature of about T c ≈ 110 K. Unexpectedly, we observe a persistent band splitting up to room temperature, which is consistent with an order-disorder contribution of local dipoles to the phase transition that requires the presence of fluctuating dipoles above T c . We conclude that no topological surface state can occur under these conditions at the (111) surface of SnTe, at odds with recent literature.

Published
2024
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