Your search keyword '"Minár, Ján"' showing total 258 results

1. Layered Multiple Scattering Approach to Hard X-ray Photoelectron Diffraction: Theory and Application

Author

Vo, Trung-Phuc, Tkach, Olena, Tricot, Sylvain, Sebilleau, Didier, Braun, Jurgen, Pulkkinen, Aki, Winkelmann, Aimo, Fedchenko, Olena, Lytvynenko, Yaryna, Vasilyev, Dmitry, Elmers, Hans-Joachim, Schonhense, Gerd, and Minar, Jan

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Photoelectron diffraction (PED) is a powerful and essential experimental technique for resolving the structure of surfaces with sub-angstrom resolution. In the high energy regime, researchers in angle-resolved photoemission spectroscopy (ARPES) observe modulating patterns attributed to X-ray-PED (XPD) effects. This is accompanied by other challenges such as low cross-sections, significant photon momentum transfer, and non-negligible phonon scattering. Overall, XPD is not only an advantageous approach but also exhibits unexpected effects. To disentangle these diffraction influences, we present a PED implementation for the SPRKKR package that utilizes multiple scattering theory and a one-step model in the photoemission process. Unlike real-space implementations of the multiple scattering XPD formalism, we propose a k-space implementation based on the layer KKR method. The main advantage of this method is its ability to address a very broad kinetic energy range (20-8000 eV) without convergence problems related to angular momentum and cluster size. Furthermore, the so-called alloy analogy model can be used to simulate XPD at finite temperatures as well as XPD effects observed in soft and hard X-ray ARPES. For practical applications, we have calculated the circular dichroism in angular distributions (CDAD) associated with core-level photoemission of 2p from Si(100) and 3p from Ge(100). Photoelectrons are excited by hard X-rays (6000 eV) with right and left circularly polarized radiation (RCP and LCP, respectively).

Published

2024

2. Artical Functionalization of structural and electronic properties of multiferroic SrTiO3 thin films

Author

Jansa, Zdeněk, Prušáková, Lucie, Jansová, Štěpánka, Calta, Pavel, Šutta, Pavol, and Minár, Ján

Subjects

Condensed Matter - Materials Science

Abstract

This study examines the application of transition metal-doped SrTiO3 in photovoltaic technologies, such as photocatalysis. The core objective is to evaluate how different dopants influence the structural and electronic characteristics of the well-known perovskite, SrTiO3 (STO). By incorporating dopants, particularly transition metals, the material's physical properties can be enhanced by addressing limitations such as the large gap in the valence band. This study aims to determine the impact of these metals on factors like crystallite size, internal stress levels, electron-hole pair distribution in the valence band, and the shift in the electromagnetic spectrum toward the visible range. The primary focus is on assessing nickel's (Ni) influence on these properties, with additional investigation into the effects of yttrium (Y) and iron (Fe). Several experimental methods were employed to analyze the structural and electronic properties of SrTiO3. The same procedures were applied consistently across all samples, with the sole exception being the high-temperature XRD experiments, as described in the text. The techniques used include magnetron pulse deposition for sample preparation, followed by X-ray diffraction (XRD), scanning electron microscopy (SEM), and X-ray photoelectron spectroscopy (XPS). After conducting the experiments, the collected data were evaluated and used to guide subsequent steps. Finally, all data were consolidated and analyzed comprehensively., Comment: 15 pages, 9 figures

Published

2024

3. Persistent flat band splitting and strong selective band renormalization in a kagome magnet thin film

Author

Ren, Zheng, Huang, Jianwei, Tan, Hengxin, Biswas, Ananya, Pulkkinen, Aki, Zhang, Yichen, Xie, Yaofeng, Yue, Ziqin, Chen, Lei, Xie, Fang, Allen, Kevin, Wu, Han, Ren, Qirui, Rajapitamahuni, Anil, Kundu, Asish, Vescovo, Elio, Kono, Junichiro, Morosan, Emilia, Dai, Pengcheng, Zhu, Jian-Xin, Si, Qimiao, Minár, Ján, Yan, Binghai, and Yi, Ming

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Magnetic kagome materials provide a fascinating playground for exploring the interplay of magnetism, correlation and topology. Many magnetic kagome systems have been reported including the binary FemXn (X=Sn, Ge; m:n = 3:1, 3:2, 1:1) family and the rare earth RMn6Sn6 (R = rare earth) family, where their kagome flat bands are calculated to be near the Fermi level in the paramagnetic phase. While partially filling a kagome flat band is predicted to give rise to a Stoner-type ferromagnetism, experimental visualization of the magnetic splitting across the ordering temperature has not been reported for any of these systems due to the high ordering temperatures, hence leaving the nature of magnetism in kagome magnets an open question. Here, we probe the electronic structure with angle-resolved photoemission spectroscopy in a kagome magnet thin film FeSn synthesized using molecular beam epitaxy. We identify the exchange-split kagome flat bands, whose splitting persists above the magnetic ordering temperature, indicative of a local moment picture. Such local moments in the presence of the topological flat band are consistent with the compact molecular orbitals predicted in theory. We further observe a large spin-orbital selective band renormalization in the Fe d_xy+d_(x^2-y^2 ) spin majority channel reminiscent of the orbital selective correlation effects in the iron-based superconductors. Our discovery of the coexistence of local moments with topological flat bands in a kagome system echoes similar findings in magic-angle twisted bilayer graphene, and provides a basis for theoretical effort towards modeling correlation effects in magnetic flat band systems.

Published

2024

4. Anionic disorder and its impact on the surface electronic structure of oxynitride photoactive semiconductors

Author

Hartl, Anna, Minár, Ján, Constantinou, Procopios, Roddatis, Vladimir, Alarab, Fatima, Müller, Arnold M., Vockenhuber, Christof, Schmitt, Thorsten, Pergolesi, Daniele, Strocov, Thomas Lippert Vladimir N., and Shepelin, Nick A.

Subjects

Condensed Matter - Materials Science

Abstract

The conversion of solar energy into chemical energy, stored in the form of hydrogen, bears enormous potential as a sustainable fuel for powering emerging technologies. Photoactive oxynitrides are promising materials for splitting water into molecular oxygen and hydrogen. However, one of the issues limiting widespread commercial use of oxynitrides is the degradation during operation. While recent studies have shown the loss of nitrogen, its relation to the reduced efficiency has not been directly and systematically addressed with experiments. In this study, we demonstrate the impact of the anionic stoichiometry of BaTaO$_x$N$_y$ on its electronic structure and functional properties. Through experimental ion scattering, electron microscopy, and photoelectron spectroscopy investigations, we determine the anionic composition ranging from the bulk towards the surface of BaTaO$_x$N$_y$ thin films. This further serves as input for band structure computations modeling the substitutional disorder of the anion sites. Combining our experimental and computational approaches, we reveal the depth-dependent elemental composition of oxynitride films, resulting in downward band bending and the loss of semiconducting character towards the surface. Extending beyond idealized systems, we demonstrate the relation between the electronic properties of real oxynitride photoanodes and their performance, providing guidelines for engineering highly efficient photoelectrodes and photocatalysts for clean hydrogen production., Comment: 19 pages, 5 figures

Published

2024

5. Crystallite size and microstrain in the structure of SrTiO3 formed by magnetron deposition with and without O2 flow through the deposition chambre

Author

Jansa, Zdeněk, Jansová, Štěpánka, Nedvědová, Lucie, and Minár, Ján

Subjects

Condensed Matter - Materials Science

Abstract

Transition metal oxides, which have a perovskite structure, have received much attention in recent decades. This is because of the very suitable properties that can be used in various industries. One of the fields where the properties of Perovskites can and have already been applied is in the power industry. Experimental studies of the last few years have reliably demonstrated that, using simple modifications, perovskite oxides can be used in applications utilizing direct sunlight and photocatalytic applications. The original strontium titanate oxide SrTiO3 (abbreviated STO) is only able to use the UV component of incident radiation and is inactive in visible light, remaining transparent to visible light. The reason for this state is its wide band gap, which at room temperature has a value of 3.2 - 3.25 eV. Studies have shown that doping the structure of these oxides with transition metals (TM) can cause a shift in the valence and/or conduction band. This is because of the 3d dopant bands that create new energy levels in the mentioned band gap, effectively reducing it. One of the elements of the TM group is nickel. According to some studies, it is likely that the Ni ion occurs in the cubic structure of STO in the form of Ni2+ and substitutes the Ti4+ sites. In the case of using this dopant, the shift of the absorption edge of STO:Nix relative to NiO was found to be 1.1 eV. The present work investigates the differences in the structure of STO:Nix prepared by magnetron deposition method with different dopant amount settings. At the same time, the difference in structure was observed when prepared under vacuum with Ar working gas and when O2 was flowed through the deposition chamber. The premise of this experiment was to verify the formation of oxygen vacancies in the STO structure on which the photocatalytic phenomenon could occur., Comment: 12 pages, 11 figures, 1 table Conference Struktura 2024

Published

2024

6. Two-dimensional to bulk crossover of the WSe$_2$ electronic band structure

Author

Fèvre, Patrick Le, Salazar, Raphaël, Jamet, Matthieu, Bertran, François, Bigi, Chiara, Ourghi, Abdelkarim, Vergnaud, Céline, Pulkkinen, Aki, Minar, Jan, Jaouen, Thomas, and Rault, Julien

Subjects

Condensed Matter - Materials Science

Abstract

Transition Metal Dichalcogenides (TMD) are layered materials obtained by stacking two-dimensional sheets weakly bonded by van der Waals interactions. In bulk TMD, band dispersions are observed in the direction normal to the sheet plane (z-direction) due to the hybridization of out-of-plane orbitals but no kz-dispersion is expected at the single-layer limit. Using angle-resolved photoemission spectroscopy, we precisely address the two-dimensional to three-dimensional crossover of the electronic band structure of epitaxial WSe$_2$ thin films. Increasing number of discrete electronic states appears in given kz-ranges while increasing the number of layers. The continuous bulk dispersion is nearly retrieved for 6-sheet films. These results are reproduced by calculations going from a relatively simple tight-binding model to a sophisticated KKR-Green's function calculation. This two-dimensional system is hence used as a benchmark to compare different theoretical approaches.

Published

2024

7. The effects of V doping on the intrinsic properties of SmFe10Co2 alloys: a theoretical investigation

Author

Benea, Diana, Pop, Viorel, and Minár, Jan

Subjects

Condensed Matter - Materials Science

Abstract

The present study focuses on the intrinsic properties of the SmFe10Co2-xVx (x = 0-2) alloys, which includes the SmFe10Co2 alloy, one of the most promising permanent magnets with the ThMn12 type of structure due to its large saturation magnetization (1.78 T), high Curie temperature (Tc = 859 K), and anisotropy field (12 T) experimentally obtained. Unfortunately, its low coercivity (<0.4 T) hinders its use in permanent magnet applications. The effect of V-doping on magnetization, magnetocrystalline anisotropy energy, and Curie temperature is investigated by electronic band structure calculations. The spin-polarized fully relativistic Korringa-Kohn-Rostoker (SPR-KKR) band structure method, which employs the coherent potential approximation (CPA) to deal with substitutional disorder, has been used. The Hubbard-U correction to local spin density approximation (LSDA +U) was used to account for the large correlation effects due to the 4f electronic states of Sm. The computed magnetic moments and magnetocrystalline anisotropy energies were compared with existing experimental data to validate the theoretical approach's reliability. The exchange-coupling parameters from the Heisenberg model were used for obtaining the mean-field estimated Curie temperature. The magnetic anisotropy energy was separated into contributions from transition metals and Sm, and its relationships with the local environment, interatomic distances, and valence electron delocalization were analyzed. The suitability of the hypothetical SmFe10CoV alloy for permanent magnet manufacture was assessed using the calculated anisotropy field, magnetic hardness, and intrinsic magnetic properties., Comment: 21 pages, 5 figures

Published

2024

8. Identification of asbestos fibres from soil sediments in the Pilsen region of the Czech Republic and the impact of these minerals on the health of the local population

Author

Jansová, Štěpánka, Jansa, Zdeněk, Nedvědová, Lucie, and Minár, Ján

Subjects

Condensed Matter - Materials Science

Abstract

Asbestos is the term for silicate minerals with a typical fibrous structure and crystallise as separable fibres that can be released into the environment as a result of natural processes and anthropogenic activities. There is a need to intensify geo-environmental monitoring of the occurrence of natural asbestos on a global scale. The study of this material is important to clarify the impact of asbestos on public health and to have an accurate knowledge of the requirements for asbestos replacement materials. At present, the technical as well as the ecological reasons for switching to these fibres are difficult, as asbestos replacement materials are subject to considerable technological and economic demands, as well as demands for their biological safety. The aim of this paper is to summarize the current knowledge regarding the vast issue of asbestos occurrence, to seek to establish an appropriate methodology for detecting the presence of asbestos in soil sediments, to identify the exact types of asbestos from a series of samples, to highlight its impact on public health, and to emphasize the need for deliberate mapping of the natural occurrence of asbestos and its inclusion in the laws and decrees of the Ministry of the Environment. Samples were analysed by electron microscopy and X-ray diffraction and compared with standards or available literature. The measurements demonstrated the presence of asbestos in the site sediments and identified specific types of asbestos. The conclusion of this work is the confirmation of the presence of asbestos in all samples, including its most dangerous types, which can cause very serious diseases. In this context, the mechanism of asbestos-related diseases will be further addressed, which is linked to the size and shape of the individual fibres, the chemical composition of the asbestos types and the links between their basic structural units., Comment: 14 pages, 8 figures, 4 tables

Published

2024

9. Nature of the metallic and in-gap states in Ni-doped SrTiO$_3$

Author

Alarab, Fatima, Hricovini, Karol, Leikert, Berengar, Richter, Christine, Schmitt, Thorsten, Sing, Michael, Claessen, Ralph, Minár, Ján, and Strocov, Vladimir N.

Subjects

Condensed Matter - Materials Science

Abstract

Epitaxial thin films of SrTiO$_3$(100) doped with 6% and 12% Ni are studied with resonant angle-resolved photoelectron spectroscopy (ARPES) at the Ti and Ni L2,3-edges. We find that the Ni doping shifts the valence band (VB) of pristine SrTiO$_3$ towards the Fermi level (p-doping) and reduces its band gap. This is accompanied by an upward energy shift of the Ti t2g-derived mobile electron system (MES). Thereby, the in-plane dxy-derived bands reduce the embedded electron density, as evidenced by progressive reduction of their Fermi momentum with the Ni concentration, and the out-of-plane dxz/yz-derived bands depopulate, making the MES purely two-dimensional. Furthermore, the Ti and Ni L2,3-edge resonant photoemission is used to identify the Ni 3d impurity state in the vicinity of the valence-band maximum, and decipher the full spectrum of the VO-induced in-gap states originating from the Ni atoms, Ti atoms, and from their hybridized orbitals. Our experimental information about the dependence of the valence bands, MES and in-gap states in Ni-doped SrTiO$_3$ may help development of this material towards its device applications associated with the reduced optical band gap.

Published

2023

10. k-dependent proximity-induced modulation of spin-orbit interaction in MoSe2 interfaced with amorphous Pb

Author

Alarab, Fatima, Minár, Ján, Constantinou, Procopios, Nafday, Dhani, Schmitt, Thorsten, Wang, Xiaoqiang, and Strocov, Vladimir N.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

The ability to modulate the spin-orbit (SO) interaction is crucial for engineering a wide range of spintronics-based quantum devices, extending from state-of-the-art data storage to materials for quantum computing. The use of proximity-induced effects for this purpose may become the mainstream approach, whereas their experimental verification using angle-resolved photoelectron spectroscopy (ARPES) has so far been elusive. Here, using the advantages of soft-X-ray ARPES on its probing depth and intrinsic resolution in three-dimensional momentum k, we identify a distinct modulation of the SO interaction in a van der Waals semiconductor (MoSe2) proximitized to a high-Z metal (Pb), and measure its variation through the k-space. The strong SO field from Pb boosts the SO splitting by up to 30% at the H-point of the bulk Brillouin zone, the spin-orbit hotspot of MoSe2. Tunability of the splitting via the Pb thickness allows its tailoring to particular applications in emerging quantum devices.

Published

2023

11. Persistence of structural distortion and bulk band Rashba splitting in SnTe above its ferroelectric critical temperature

Author

Chassot, Frédéric, Pulkkinen, Aki, Kremer, Geoffroy, Zakusylo, Tetiana, Krizman, Gauthier, Hajlaoui, Mahdi, Dil, J. Hugo, Krempaský, Juraj, Minár, Ján, Springholz, Gunther, and Monney, Claude

Subjects

Condensed Matter - Materials Science

Abstract

The ferroelectric semiconductor $\alpha$-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 last 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 $\alpha$-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 $T_c\sim 110$ K. Unexpectedly, we observe a persistent band splitting up to room temperature, which is consistent with an order-disorder contribution to the phase transition that requires the presence of fluctuating local dipoles above $T_c$. We conclude that no topological surface state can occur at the (111) surface of SnTe, at odds with recent literature., Comment: 26 pages, 8 figures

Published

2023

12. Ultrafast Hidden Spin Polarization Dynamics of Bright and Dark Excitons in 2H-WSe$_2$

Author

Fanciulli, Mauro, Bresteau, David, Gaudin, Jérome, Dong, Shuo, Géneaux, Romain, Ruchon, Thierry, Tcherbakoff, Olivier, Minár, Ján, Heckmann, Olivier, Richter, Maria Christine, Hricovini, Karol, and Beaulieu, Samuel

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Optics

Abstract

We performed spin-, time- and angle-resolved extreme ultraviolet photoemission spectroscopy (STARPES) of excitons prepared by photoexcitation of inversion-symmetric 2H-WSe$_2$ with circularly polarized light. The very short probing depth of XUV photoemission permits selective measurement of photoelectrons originating from the top-most WSe$_2$ layer, allowing for direct measurement of hidden spin polarization of bright and momentum-forbidden dark excitons. Our results reveal efficient chiroptical control of bright excitons' hidden spin polarization. Following optical photoexcitation, intervalley scattering between nonequivalent K-K' valleys leads to a decay of bright excitons' hidden spin polarization. Conversely, the ultrafast formation of momentum-forbidden dark excitons acts as a local spin polarization reservoir, which could be used for spin injection in van der Waals heterostructures involving multilayer transition metal dichalcogenides.

Published

2023

13. Collective topological spin dynamics in a correlated spin glass

Author

Krempaský, Juraj, Springholz, Gunther, D'Souza, Sunil Wilfred, Caha, Ondřej, Gmitra, Martin, Ney, Andreas, Vaz, Carlos Antonio Fernandez, Piamonteze, Cinthia, Fanciulli, Mauro, Kriegner, Dominik, Krieger, Jonas A., Prokscha, Thomas, Salman, Zaher, Minár, Jan, and Dil, J. Hugo

Subjects

Condensed Matter - Materials Science

Abstract

The interplay between spin-orbit interaction (SOI) and magnetic order is currently one of the most active research fields in condensed matter physics and leading the search for materials with novel and tunable magnetic and spin properties. Here we report on a variety of unexpected and unique observations in thin multiferroic \Ge$_{1-x}$Mn$_x$Te films. The ferrimagnetic order in this ferroelectric semiconductor is found to reverse with current pulses six orders of magnitude lower as for typical spin-orbit torque systems. Upon a switching event, the magnetic order spreads coherently and collectively over macroscopic distances through a correlated spin-glass state. Lastly, we present a novel methodology to controllably harness this stochastic magnetization dynamics, allowing us to detect spatiotemporal nucleation of topological spin textures we term ``skyrmiverres''., Comment: 26 pages, 10 figures, 2 tables

Published

2022

14. Dependence of the electronic structure of $\beta$-Si$_{6-z}$Al$_{z}$O$_{z}$N$_{8-z}$ on the (Al,O) concentration $z$ and on the temperature

Author

Khan, Saleem Ayaz, Šipr, Ondřej, Vackář, Jiří, and Minár, Ján

Subjects

Condensed Matter - Materials Science

Abstract

SiAlON is a prominent example of systems suitable as hosts for creating materials for light-emitting diodes (LEDs). In this work, the electronic structure of a series of semiordered and disordered SiAlON systems is investigated by means of ab initio calculations, using the FLAPW and Green function KKR methods. Finite temperature effects are included by averaging over thermodynamic configurations within the alloy analogy model. We found that the dependence of the electronic structure on the (Al,O) concentration $z$ is similar for semiordered and disordered structures. The electronic band gap decreases with increasing $z$ by about 1.5 eV when going from $z$=0 to $z$=2. States at the top of the valence band are mostly associated with N atoms whereas the states at the bottom of the conduction band are mostly derived from O~atoms. Increasing the temperature leads to a shift of the bottom of the conduction band to lower energies. The amount of this shift increases with increasing $z$., Comment: arXiv admin note: substantial text overlap with arXiv:2001.02150

Published

2022

15. Geometry-induced spin-filtering in photoemission maps from WTe$_2$ surface states

Author

Heider, Tristan, Bihlmayer, Gustav, Schusser, Jakub, Reinert, Friedrich, Minár, Jan, Blügel, Stefan, Schneider, Claus M., and Plucinski, Lukasz

Subjects

Condensed Matter - Materials Science

Abstract

We demonstrate that an important quantum material WTe$_2$ exhibits a new type of geometry-induced spin-filtering effect in photoemission, stemming from low symmetry that is responsible for its exotic transport properties. Through the laser-driven spin-polarized angle-resolved photoemission Fermi surface mapping, we showcase highly asymmetric spin textures of electrons photoemitted from the surface states of WTe$_2$. Such asymmetries are not present in the initial state spin textures, which are bound by the time-reversal and crystal lattice mirror plane symmetries. The findings are reproduced qualitatively by theoretical modeling within the one-step model photoemission formalism. The effect could be understood within the free-electron final state model as an interference due to emission from different atomic sites. The observed effect is a manifestation of time-reversal symmetry breaking of the initial state in the photoemission process, and as such it cannot be eliminated, but only its magnitude influenced, by special experimental geometries., Comment: 5 pages, 3 figures

Published

2022

16. Field-induced ultrafast modulation of Rashba coupling at room temperature in ferroelectric $\alpha$-GeTe(111)

Author

Kremer, Geoffroy, Maklar, Julian, Nicolaï, Laurent, Nicholson, Christopher W., Yue, Changming, Silva, Caio, Werner, Philipp, Dil, J. Hugo, Krempaský, Juraj, Springholz, Gunther, Ernstorfer, Ralph, Minár, Jan, Rettig, Laurenz, and Monney, Claude

Subjects

Condensed Matter - Materials Science

Abstract

Rashba materials have appeared as an ideal playground for spin-to-charge conversion in prototype spintronics devices. Among them, $\alpha$-GeTe(111) is a non-centrosymmetric ferroelectric (FE) semiconductor for which a strong spin-orbit interaction gives rise to giant Rashba coupling. Its room temperature ferroelectricity was recently demonstrated as a route towards a new type of highly energy-efficient non-volatile memory device based on switchable polarization. Currently based on the application of an electric field, the writing and reading processes could be outperformed by the use of femtosecond (fs) light pulses requiring exploration of the possible control of ferroelectricity on this timescale. Here, we probe the room temperature transient dynamics of the electronic band structure of $\alpha$-GeTe(111) using time and angle-resolved photoemission spectroscopy (tr-ARPES). Our experiments reveal an ultrafast modulation of the Rashba coupling mediated on the fs timescale by a surface photovoltage (SPV), namely an increase corresponding to a 13 % enhancement of the lattice distortion. This opens the route for the control of the FE polarization in $\alpha$-GeTe(111) and FE semiconducting materials in quantum heterostructures., Comment: 31 pages, 12 figures

Published

2022

17. Electric field control of magnons in magnetic thin films: ab initio predictions for 2D metallic heterostructures

Author

Marmodoro, Alberto, Mankovsky, Sergiy, Ebert, Hubert, Minár, Jan, and Šipr, Ondřej

Subjects

Condensed Matter - Materials Science

Abstract

We explore possibilities for control of magnons in two-dimensional heterostructures by an external electric field acting across a dielectric barrier. By performing ab-initio calculations for a Fe monolayer and a Fe bilayer, both suspended in vacuum and deposited on Cu(001), we demonstrate that external electric field can significantly modify magnon lifetimes and that these changes can be related to field-induced changes in the layer-resolved Bloch spectral functions. For systems with more magnon dispersion branches, the gap between high- and low-energy eigenmodes varies with the external field. These effects are strongly influenced by the substrate. Considerable variability in how the magnon spectra are sensitive to the external electric field can be expected, depending on the substrate and on the thickness of the magnetic layer.

Published

2022

18. Dynamics of lattice disorder in perovskite materials, polarization nanoclusters and ferroelectric domain wall structures

Author

Očenášek, Jan, Minár, Ján, and Alcalá, Jorge

Published

2023

19. Understanding the roles of electronic effect in CO on Pt-Sn alloy surface via band structure measurements

Author

Jung, Jongkeun, Nicolai, Sungwoo Kang Laurent, Hong, Jisook, Minár, Jan, Song, Inkyung, Kyung, Wonshik, Cho, Soohyun, Kim, Beomseo, Denlinger, Jonathan D., Aires, Francisco J. C. S., Ehret, Eric, Ross, Philip N., Shim, Jihoon, Nemšák, Slavomir, Noh, Doyoung, Han, Seungwu, Kim, Changyoung, and Mun, Bongjin S.

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics

Abstract

Using angle-resolved photoemission spectroscopy, we show the direct evidence of charge transfer between adsorbed molecules and metal substrate, i.e. chemisorption of CO on Pt(111) and Pt-Sn/Pt(111) 2x2 surfaces. The observed band structure shows a unique signature of charge transfer as CO atoms are adsorbed,revealing the roles of specific orbital characters participating in the chemisorption process. As the coverage of CO increases, the degree of charge transfer between CO and Pt shows clear difference to that of Pt-Sn. With comparison to DFT calculation results, the observed distinct features in the band structure are interpreted as backdonation bonding states of Pt molecular orbital to the 2{\pi} orbital of CO. Furthermore, the change in the surface charge concentration, measured from the Fermi surface area, shows Pt surface has a larger charge concentration change than Pt-Sn surface upon CO adsorption. The difference in the charge concentration change between Pt and Pt-Sn surfaces reflects the degree of electronic effects during CO adsorption on Pt-Sn., Comment: 15 pages, 9 figures, 2 tables

Published

2021

20. Highly superlinear photogalvanic effects in (Bi$_{0.3}$Sb$_{0.7}$)$_2$(Te$_{0.1}$Se$_{0.9}$)$_3$: Probing 3D topological insulator surface states at room temperature

Author

Danilov, Sergey N., Golub, Leonid E., Mayer, Thomas, Beer, Andreas, Binder, Stefan, Mönch, Erwin, Minar, Jan, Kronseder, Matthias, Back, Christian. H., Bougeard, Dominique, and Ganichev, Sergey D.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report on the observation of complex nonlinear intensity dependence of the circular and linear photogalvanic currents induced by infrared radiation in compensated (Bi$_{0.3}$Sb$_{0.7}$)$_2$(Te$_{0.1}$Se$_{0.9}$)$_3$ 3D topological insulators. The photocurrents are induced by direct optical transitions between topological surface and bulk states. We show that an increase of the radiation intensity results first in a highly superlinear raise of the amplitude of both types of photocurrents, whereas at higher intensities the photocurrent saturates. Our analysis of the observed nonlinearities shows that the superlinear behavior of the photocurrents is caused by a heating of the electron gas, while the saturation is induced by a slow relaxation of the photoexcited carriers resulting in absorbance bleaching. The observed nonlinearities give access to the Fermi level position with respect to the Dirac point and the energy relaxation times of Dirac fermions providing an experimental room temperature probe for topological surface states., Comment: 12 pages, 7 figures

Published

2021

21. Unveiling the Orbital Texture of 1T-TiTe$_2$ using Intrinsic Linear Dichroism in Multidimensional Photoemission Spectroscopy

Author

Beaulieu, Samuel, Schüler, Michael, Schusser, Jakub, Dong, Shuo, Pincelli, Tommaso, Maklar, Julian, Neef, Alexander, Reinert, Friedrich, Wolf, Martin, Rettig, Laurenz, Minár, Ján, and Ernstorfer, Ralph

Subjects

Condensed Matter - Materials Science

Abstract

The momentum-dependent orbital character in crystalline solids, referred to as orbital texture, is of capital importance in the emergence of symmetry-broken collective phases such as charge density waves as well as superconducting and topological states of matter. By performing extreme ultraviolet multidimensional angle-resolved photoemission spectroscopy for two different crystal orientations linked to each other by mirror symmetry, we isolate and identify the role of orbital texture in photoemission from the transition metal dichalcogenide 1T-TiTe$_2$. By comparing our experimental results with theoretical calculations based on both a quantitative one-step model of photoemission and an intuitive tight-binding model, we unambiguously demonstrate the link between the momentum-dependent orbital orientation and the emergence of strong intrinsic linear dichroism in the photoelectron angular distributions. Our results represent an important step towards going beyond band structure (eigenvalues) mapping and learn about electronic wavefunction and orbital texture of solids by exploiting matrix element effects in photoemission spectroscopy.

Published

2021

22. Understanding the Role of Electronic Effects in CO on the Pt–Sn Alloy Surface via Band Structure Measurements

Author

Jung, Jongkeun, Kang, Sungwoo, Nicolaï, Laurent, Hong, Jisook, Minár, Ján, Song, Inkyung, Kyung, Wonshik, Cho, Soohyun, Kim, Beomseo, Denlinger, Jonathan D, Aires, Francisco José Cadete Santos, Ehret, Eric, Ross, Philip, Shim, Jihoon, Nemšák, Slavomir, Noh, Doyoung, Han, Seungwu, Kim, Changyoung, and Mun, Bongjin Simon

Subjects

angle-resolved photoelectron spectroscopy, CO adsorption, Pt alloy, p back-donation, orbital character, Inorganic Chemistry, Organic Chemistry, Chemical Engineering

Abstract

Using angle-resolved photoemission spectroscopy, we show direct evidence for charge transfer between adsorbed molecules and metal substrates, i.e., chemisorption of CO on Pt(111) and Pt–Sn/Pt(111) 2 × 2 surfaces. The observed band structures show a unique signature of charge transfer as CO atoms are adsorbed, revealing the roles of specific orbital characters participating in the chemisorption process. As the coverage of CO increases, the degree of charge transfer between CO and Pt shows a clear difference to that of Pt–Sn. With comparison to density functional theory calculation results, the observed distinct features in the band structure are interpreted as back-donation bonding states formed between the Pt molecular orbital and the 2π orbital of CO. Furthermore, the change in the surface charge concentration, measured from the Fermi surface area, shows that the Pt surface has a larger charge concentration change than the Pt–Sn surface upon CO adsorption. The differences between Pt and Pt–Sn surfaces are due to the effect of Pt–Sn intermetallic bonding on the interaction of CO with the surface.

Published

2022

23. Role of chemical disorder in tuning the Weyl points in vanadium doped Co$_2$TiSn

Author

Chaudhary, Payal, Dubey, Krishna Kant, Shukla, Gaurav K., Singh, Sanjay, Sadhukhan, Surasree, Kanungo, Sudipta, Jena, Ajit K., Lee, S. -C, Bhattacharjee, S., Minár, Jan, and D'Souza, Sunil Wilfred

Subjects

Condensed Matter - Materials Science

Abstract

The lack of time-reversal symmetry and Weyl fermions give exotic transport properties to Co-based Heusler alloys. In the present study, we have investigated the role of chemical disorder on the variation of Weyl points in Co\textsubscript{2}Ti\textsubscript{1-x}V\textsubscript{x}Sn magnetic Weyl semimetal candidate. We employ the first principle approach to track the evolution of the nodal lines responsible for the appearance of Weyl node in Co$_2$TiSn as a function of V substitution in place of Ti. By increasing the V concentration in place of Ti, the nodal line moves toward Fermi level and remains at Fermi level around the middle composition. Further increase of the V content, leads shifting of nodal line away from Fermi level. Density of state calculation shows half-metallic behavior for the entire range of composition. The magnetic moment on each Co atom as a function of V concentration increases linearly up to x=0.4, and after that, it starts decreasing. We also investigated the evolution of the Weyl nodes and Fermi arcs with chemical doping. The first-principles calculations reveal that via replacing almost half of the Ti with V, the intrinsic anomalous Hall conductivity increased twice as compared to the undoped composition. Our results indicate that the composition close to the 50\% V doped Co$_2$TiSn, will be an ideal composition for the experimental investigation of Weyl physics., Comment: 14 pages, 12 figures

Published

2021

24. Triple point fermions in ferroelectric GeTe

Author

Krempaský, Juraj, Nicolaï, Laurent, Gmitra, Martin, Chen, Houke, Fanciulli, Mauro, Guedes, Eduardo B., Caputo, Marco, Radović, Milan, Volobuev, V. V., Caha, Ondrej, Springholz, Gunther, Minár, Jan, and Dil, J. Hugo

Subjects

Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter

Abstract

Ferroelectric GeTe is unveiled to exhibit an intriguing multiple non-trivial topology of the electronic band structure due to the existence of triple-point and type-II Weyl fermions, which goes well beyond the giant Rashba spin splitting controlled by external fields as previously reported. Using spin- and angle-resolved photoemission spectroscopy combined with ab initio density functional theory, the unique spin texture around the triple point caused by the crossing of one spin degenerate and two spin-split bands along the ferroelectric crystal axis is derived. This consistently reveals spin winding numbers that are coupled with time reversal symmetry and Lorentz invariance, which are found to be equal for both triple-point pairs in the Brillouin zone. The rich manifold of effects opens up promising perspectives for studying non-trivial phenomena and multi-component fermions in condensed matter systems., Comment: 5 pages, 5 figures

Published

2020

25. Surface band characters of Weyl semimetal candidate material MoTe$_2$ revealed by one-step ARPES theory

Author

Ono, Ryota, Marmodoro, Alberto, Schusser, Jakub, Nakata, Yositaka, Schwier, Eike F., Braun, Jürgen, Ebert, Hubert, Minár, Ján, Sakamoto, Kazuyuki, and Krüger, Peter

Subjects

Condensed Matter - Materials Science

Abstract

The layered 2D-material MoTe$_2$ in the T$_d$ crystal phase is a semimetal which has theoretically been predicted to possess topologically non-trivial bands corresponding to Weyl fermions. Clear experimental evidence by angle-resolved photoemission spectroscopy (ARPES) is, however, lacking, which calls for a careful examination of the relation between ground state band structure calculations and ARPES intensity plots. Here we report a study of the near Fermi-energy band structure of MoTe$_2$(T$_d$) by means of ARPES measurements, density functional theory, and one-step-model ARPES calculations. Good agreement between theory and experiment is obtained. We analyze the orbital character of the surface bands and its relation to the ARPES polarization dependence. We find that light polarization has a major efect on which bands can be observed by ARPES. For s-polarized light, the ARPES intensity is dominated by subsurface Mo d orbitals, while p-polarized light reveals the bands composed mainly derived from Te p orbitals. Suitable light polarization for observing either electron or hole pocket are determined, Comment: 11 pages, 7 figures

Published

2020

26. Minority-Spin Impurity Band in n-Type (In,Fe)As: A Materials Perspective for Ferromagnetic Semiconductors

Author

Kobayashi, Masaki, Anh, Le Duc, Minar, Jan, Khan, Walayat, Borek, Stephan, Hai, Pham Nam, Harada, Yoshihisa, Schmitt, Thorsten, Oshima, Masaharu, Fujimori, Atsushi, Tanaka, Masaaki, and Strocov, Vladimir N.

Subjects

Condensed Matter - Materials Science

Abstract

Fully understanding the properties of n-type ferromagnetic semiconductors (FMSs), complementary to the mainstream p-type ones, is a challenging goal in semiconductor spintronics because ferromagnetism in n-type FMSs is theoretically non-trivial. Soft-x-ray angle-resolved photoemission spectroscopy (SX-ARPES) is a powerful approach to examine the mechanism of carrier-induced ferromagnetism in FMSs. Here our SX-ARPES study on the prototypical n-type FMS (In,Fe)As reveals the entire band structure including the Fe-3d impurity bands (IBs) and the host InAs ones, and provides direct evidence for electron occupation of the InAs-derived conduction band (CB). A minority-spin Fe-3d IB is found to be located just below the conduction-band minimum (CBM). The IB is formed by the hybridization of the unoccupied Fe-3d states with the occupied CBM of InAs in a spin-dependent way, resulting in the large spin polarization of CB. The band structure with the IB is varied with band filling, which cannot be explained by the rigid-band picture, suggesting a unified picture for realization of carrier-induced ferromagnetism in FMS materials., Comment: 24 pages, 7 figures

Published

2020

27. Revealing Hidden Orbital Pseudospin Texture with Time-Reversal Dichroism in Photoelectron Angular Distributions

Author

Beaulieu, Samuel, Schusser, Jakub, Dong, Shuo, Schüler, Michael, Pincelli, Tommaso, Dendzik, Maciej, Maklar, Julian, Neef, Alexander, Ebert, Hubert, Hricovini, Karol, Wolf, Martin, Braun, Jürgen, Rettig, Laurenz, Minár, Jan, and Ernstorfer, Ralph

Subjects

Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter

Abstract

We performed angle-resolved photoemission spectroscopy (ARPES) of bulk 2H-WSe$_2$ for different crystal orientations linked to each other by time-reversal symmetry. We introduce a new observable called time-reversal dichroism in photoelectron angular distributions (TRDAD), which quantifies the modulation of the photoemission intensity upon effective time-reversal operation. We demonstrate that the hidden orbital pseudospin texture leaves its imprint onto TRDAD, due to multiple orbitals interference effects in photoemission. Our experimental results are in quantitative agreement with both tight-binding model and state-of-the-art fully relativistic calculations performed using the one-step model of photoemission. While spin-resolved ARPES probes the spin component of entangled spin-orbital texture in multiorbital systems, we unambiguously demonstrate that TRDAD reveals its orbital pseudospin texture counterpart.

Published

2020

28. The CECAM Electronic Structure Library and the modular software development paradigm

Author

Oliveira, Micael J. T., Papior, Nick, Pouillon, Yann, Blum, Volker, Artacho, Emilio, Caliste, Damien, Corsetti, Fabiano, de Gironcoli, Stefano, Elena, Alin M., Garcia, Alberto, Garcia-Suarez, Victor M., Genovese, Luigi, Huhn, William P., Huhs, Georg, Kokott, Sebastian, Kucukbenli, Emine, Larsen, Ask H., Lazzaro, Alfio, Lebedeva, Irina V., Li, Yingzhou, Lopez-Duran, David, Lopez-Tarifa, Pablo, Luders, Martin, Marques, Miguel A. L., Minar, Jan, Mohr, Stephan, Mostofi, Arash A., O'Cais, Alan, Payne, Mike C., Ruh, Thomas, Smith, Daniel G. A., Soler, Jose M., Strubbe, David A., Tancogne-Dejean, Nicolas, Tildesley, Dominic, Torrent, Marc, and Yu, Victor Wen-zhe

Subjects

Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

First-principles electronic structure calculations are very widely used thanks to the many successful software packages available. Their traditional coding paradigm is monolithic, i.e., regardless of how modular its internal structure may be, the code is built independently from others, from the compiler up, with the exception of linear-algebra and message-passing libraries. This model has been quite successful for decades. The rapid progress in methodology, however, has resulted in an ever increasing complexity of those programs, which implies a growing amount of replication in coding and in the recurrent re-engineering needed to adapt to evolving hardware architecture. The Electronic Structure Library (\esl) was initiated by CECAM (European Centre for Atomic and Molecular Calculations) to catalyze a paradigm shift away from the monolithic model and promote modularization, with the ambition to extract common tasks from electronic structure programs and redesign them as free, open-source libraries. They include "heavy-duty" ones with a high degree of parallelisation, and potential for adaptation to novel hardware within them, thereby separating the sophisticated computer science aspects of performance optimization and re-engineering from the computational science done by scientists when implementing new ideas. It is a community effort, undertaken by developers of various successful codes, now facing the challenges arising in the new model. This modular paradigm will improve overall coding efficiency and enable specialists (computer scientists or computational scientists) to use their skills more effectively. It will lead to a more sustainable and dynamic evolution of software as well as lower barriers to entry for new developers., Comment: Revised version as finally accepted by J. Chem. Phys. to appear within the Special Topic in Electronic Structure Software (version prior to JCP's typesetting and proofs)

Published

2020

29. One step model of photo-emission at finite temperatures: spin fluctuations of Fe(001)

Author

Minar, Jan, Mankovsky, Sergey, Braun, Jurgen, and Ebert, Hubert

Subjects

Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons

Abstract

Various technical developments extended the potential of angle-resolved photoemission (ARPES) tremendously during the last twenty years. In particular improved momentum, energy and spin resolution as well as the use of photon energies from few eV up to several keV makes ARPES a rather unique tool to investigate the electronic properties of solids and surfaces. With our work we present a generalization of the state of the art description of the photoemission process, the so called one-step model that describes excitation, transport to the surface and escape into the vacuum in a coherent way. In particular, we present a theoretical description of temperature-dependent ARPES with a special emphasis on spin fluctuations. Finite temperature effects are included within the so called alloy analogy model which is based on the coherent potential approximation and this way allows to describe uncorrelated lattice vibrations in combination with spin fluctuations quantitatively on the same level of accuracy. To demonstrate the applicability of our approach a corresponding numerical analysis has been applied to spin- and angle-resolved photoemission of Fe(100) at finite temperatures., Comment: Submitted to PRB

Published

2020

30. Bulk and surface electronic states in the dosed semimetallic HfTe$\boldsymbol{_2}$

Author

Youbi, Zakariae El, Jung, Sung Won, Mukherjee, Saumya, Fanciulli, Mauro, Schusser, Jakub, Heckmann, Olivier, Richter, Christine, Minár, Ján, Hricovini, Karol, Watson, Matthew D., and Cacho, Cephise

Subjects

Condensed Matter - Materials Science

Abstract

The dosing of layered materials with alkali metals has become a commonly used strategy in ARPES experiments. However, precisely what occurs under such conditions, both structurally and electronically, has remained a matter of debate. Here we perform a systematic study of 1T-HfTe$_2$, a prototypical semimetal of the transition metal dichalcogenide family. By utilizing photon energy-dependent angle-resolved photoemission spectroscopy (ARPES), we have investigated the electronic structure of this material as a function of Potassium (K) deposition. From the k$_z$ maps, we observe the appearance of 2D dispersive bands after electron dosing, with an increasing sharpness of the bands, consistent with the wavefunction confinement at the topmost layer. In our highest-dosing cases, a monolayer-like electronic structure emerges, presumably as a result of intercalation of the alkali metal. Here, by bringing the topmost valence band below $E_F$, we can directly measure a band overlap of $\sim$ 0.2 eV. However, 3D bulk-like states still contribute to the spectra even after considerable dosing. Our work provides a reference point for the increasingly popular studies of the alkali metal dosing of semimetals using ARPES.

Published

2020

31. Electronic structure of $\beta$-SiAlON: effect of varying Al/O concentration at finite temperatures relevant for thermal quenchin

Author

Sipr, Ondrej, Khan, Saleem Ayaz, Vackar, Jiri, Niklaus, Robin, Schmidt, Peter J., Schnick, Wolfgang, and Minar, Jan

Subjects

Condensed Matter - Materials Science

Abstract

$\beta$-Si$_{6-z}$Al$_{z}$O$_{z}$N$_{8-z}$ is a prominent example of systems suitable as hosts for creating materials for light-emitting diodes. In this work, the electronic structure of a series of ordered and disordered $\beta$-Si$_{6-z}$Al$_{z}$O$_{z}$N$_{8-z}$ systems is investigated by means of ab initio calculations, using the FLAPW and the Green function KKR methods. Finite temperature effects are included within the alloy analogy model. We found that the trends with the Al/O doping are similar for ordered and disordered structures. The electronic band gap decreases with increasing $z$ by about 1 eV when going from $z$=0 to $z$=2. The optical gap decreases analogously as the electronic band gap. The changes in the density of states (DOS) at Si and N atoms introduced by doping $\beta$-Si$_{3}$N$_{4}$ with Al and O are comparable to the DOS at Al and O atoms themselves. The bottom of the conduction band in $\beta$-Si$_{6-z}$Al$_{z}$O$_{z}$N$_{8-z}$ is formed by extended states residing on all atomic types. Increasing the temperature leads to a shift of the bottom of the conduction band to lower energies. The amount of this shift increases with increasing doping $z$., Comment: This paper contains correct but uncompleted research. We uploaded another paper arxiv:2210.17397 that contains more data, considers more aspects and explores the topic from a bit different perspective. Having this manuscript arXiv:2001.02150 at the server might create unnecessary confusion: the interested reader had better read the new paper arxiv:2210.17397

Published

2020

32. Resolving transient temperature and density during ultrafast laser ablation of aluminum

Author

Winter, Jan, Redka, David, Minár, Ján, Schmidt, Michael, and Huber, Heinz P.

Published

2023

33. Spin-, time- and angle-resolved photoemission spectroscopy on WTe$_2$

Author

Fanciulli, Mauro, Schusser, Jakub, Lee, Min-I, Youbi, Zakariae El, Heckmann, Olivier, Richter, Maria Christine, Cacho, Cephise, Spezzani, Carlo, Bresteau, David, Hergott, Jean-François, D'Oliveira, Pascal, Tcherbakoff, Olivier, Ruchon, Thierry, Minár, Jan, and Hricovini, Karol

Subjects

Condensed Matter - Materials Science

Abstract

We combined a spin-resolved photoemission spectrometer with a high-harmonic generation (HHG) laser source in order to perform spin-, time- and angle-resolved photoemission spectroscopy (STARPES) experiments on the transition metal dichalcogenide bulk WTe$_2$, a possible Weyl type-II semimetal. Measurements at different femtosecond pump-probe delays and comparison with spin-resolved one-step photoemission calculations provide insight into the spin polarization of electrons above the Fermi level in the region where Weyl points of WTe$_2$ are expected. We observe a spin accumulation above the Weyl points region, that is consistent with a spin-selective bottleneck effect due to the presence of spin polarized cone-like electronic structure. Our results support the feasibility of STARPES with HHG, which despite being experimentally challenging provides a unique way to study spin dynamics in photoemission., Comment: 6 pages, 4 figures

Published

2019

34. Bulk electronic structure of lanthanum hexaboride (LaB6) by hard x-ray angle-resolved photoelectron spectroscopy

Author

Rattanachata, Arunothai, Nicolaï, Laurent C, Martins, Henrique P, Conti, Giuseppina, Verstraete, Matthieu J, Gehlmann, Mathias, Ueda, Shigenori, Kobayashi, Keisuke, Vishik, Inna, Schneider, Claus M, Fadley, Charles S, Gray, Alexander X, Minár, Ján, and Nemšák, Slavomír

Subjects

Chemical Sciences, Physical Sciences, Condensed Matter Physics, physics.app-ph, cond-mat.mtrl-sci, Macromolecular and materials chemistry, Materials engineering, Condensed matter physics

Abstract

In the last decade rare-earth hexaborides have been investigated for their fundamental importance in condensed matter, and for their applications in advanced technological fields. Among these compounds, LaB6 has a special place, being a traditional d-band metal without additional f bands. In order to understand the bulk electronic structure of the more complex rare-earth hexaborides, in this paper we investigate the bulk electronic structure of LaB6 using tender/hard x-ray photoemission spectroscopy, measuring both core-level and angle-resolved valence-band spectra. Furthermore, we compare the La 3d core level spectrum to cluster model calculations in order to understand the bulklike core-hole screening effects. The results show that the La 3d well-screened peak is at a lower binding energy compared to the main poorly screened peak; the relative intensity between these peaks depends on how strong the hybridization is between La and B atoms. We show that the recoil effect, negligible in the soft x-ray regime, becomes prominent at higher kinetic energies for lighter elements, such as boron, but is still negligible for heavy elements, such as lanthanum. In addition, we report the bulklike band structure of LaB6 determined by tender/hard x-ray angle-resolved photoemission spectroscopy (HARPES). We compare HARPES experimental results to the free-electron final-state calculations and to the more precise one-step photoemission theory including matrix element and phonon excitation effects. The agreement between the features present in the experimental ARPES data and the theoretical calculations is very good. In addition, we consider the nature and the magnitude of phonon excitations in order to interpret HARPES experimental data measured at different temperatures and excitation energies. We demonstrate that the one-step theory of photoemission and HARPES experiments provides, at present, the only approach capable of probing, both experimentally and theoretically, true "bulklike"electronic band structure of rare-earth hexaborides and strongly correlated materials.

Published

2021

35. Soft X-ray Fermi surface tomography of palladium and rhodium via momentum microscopy

Author

Tan, Xin Liang, Hagiwara, Kenta, Chen, Ying-Jiun, Schusser, Jakub, Cojocariu, Iulia, Baranowski, Daniel, Feyer, Vitaliy, Minár, Ján, Schneider, Claus M., and Tusche, Christian

Published

2023

36. Investigation of carrier transport in ZnO and ZnO:Al thin films sputtered at different oxygen conditions

Author

Novák, Petr, Nedvědová, Lucie, Kozák, Tomáš, Šotová, Petra, Bláhová, Olga, Jansa, Zdeněk, Medlín, Rostislav, Frank Netrvalová, Marie, and Minár, Ján

Published

2023

37. Magneto-optic and transverse transport properties of non-collinear antiferromagnets

Author

Wimmer, Sebastian, Mankovsky, Sergiy, Minár, Ján, Yaresko, Alexander N., and Ebert, Hubert

Subjects

Condensed Matter - Materials Science

Abstract

Previous studies on the anomalous Hall effect in coplanar non-collinear antiferromagnets are revisited and extended to magneto-optic properties, namely magneto-optic Kerr effect (MOKE) and X-ray magnetic dichroism (XMCD). Starting from group-theoretical considerations the shape of the frequency-dependent conductivity tensor for various actual and hypothetical spin configurations in cubic and hexagonal Mn$_3X$ compounds is determined. Calculated MOKE and X-ray dichroism spectra are used to confirm these findings and to give estimates of the size of the effects. For Mn$_3$IrPt and Mn$_3$PtRh alloys the concentration dependence of the anomalous and spin Hall conductivity is studied in addition.

Published

2019

38. Surface resonance of the Heusler half metal Co2MnSi probed by SX-ARPES

Author

Lidig, Christian, Minár, Jan, Braun, Jürgen, Ebert, Hubert, Gloskovskii, Andrei, Krieger, Jonas A., Strocov, Vladimir, Kläui, Mathias, and Jourdan, Martin

Subjects

Condensed Matter - Materials Science

Abstract

Heusler compounds are promising materials for spintronics with adjustable electronic properties including 100% spin polarization at the Fermi energy. We investigate the electronic states of AlOx capped epitaxial thin films of the ferromagnetic half metal Co2MnSi ex-situ by soft X-ray angular resolved photoemission spectroscopy (SX-ARPES). Good agreement between the experimental SX- ARPES results and photoemission calculations including surface effects was obtained. In particular, we observed in line with our calculations a large photoemission intensity at the center of the Brillouin zone, which does not originate from bulk states, but from a surface resonance. This provides strong evidence for the validity of the previously proposed model based on this resonance, which was applied to explain the huge spin polarization of Co2MnSi observed by angular-integrating UV-photoemission spectroscopy., Comment: 4 pages, 4 figures

Published

2019

39. Local geometry around B atoms in B/Si(111) from polarized x-ray absorption spectroscopy

Author

Khan, Saleem Ayaz, Vondráček, Martin, Blaha, Peter, Horáková, Kateřina, Minár, Jan, Šipr, Ondřej, and Cháb, Vladimír

Subjects

Condensed Matter - Materials Science

Abstract

The arrangement of B~atoms in a doped Si(111)-$(\sqrt{3}\times\sqrt{3})R30^{\circ}$:B system was studied using near-edge x-ray absorption fine structure (NEXAFS). Boron atoms were deposited via segregation from the bulk by flashing the sample repeatedly. The positions of B~atoms are determined by comparing measured polarized (angle-dependent) NEXAFS spectra with spectra calculated for various structural models based on ab-initio total energy calculations. It is found that most of boron atoms are located in sub-surface L$_{1}^{c}$ positions, beneath a Si atom. However, depending on the preparation method a significant portion of B~atoms may be located elsewhere. A possible location of these non-L$_{1}^{c}$-atoms is at the surface, next to those Si atoms which form the $(\sqrt{3}\times\sqrt{3})R30^{\circ}$ reconstruction., Comment: 9 pages, 8 figures

Published

2019

40. Electronic structure of Bi nanolines on InAs(100)

Author

Nafday, Dhani, Richter, Christine, Heckmann, Olivier, Wang, Weimin, Mariot, Jean-Michel, Djukic, Uros, Vobornik, Ivana, Lefevre, Patrick, Taleb-Ibrahimi, Amina, Bertran, Franco̧is, Rault, Julien, Nicolaï, Laurent, Ong, Chin Shen, Thunström, Patrik, Hricovini, Karol, Minár, Ján, and Di Marco, Igor

Published

2023

41. Ca and S K-edge XANES of CaS calculated by different methods: influence of full potential, core hole and Eu doping

Author

Sipr, Ondrej, Khan, Wilayat, Joly, Yves, and Minar, Jan

Subjects

Condensed Matter - Materials Science

Abstract

Ca and S K-edge spectra of CaS are calculated by the full-potential Green's function multiple-scattering method, by the FLAPW method, and by the finite difference method. All three techniques lead to similar spectra. Some differences remain close to the edge, both when comparing different calculations with each other and when comparing the calculations with earlier experimental data. We find that using the full potential does not lead to significant improvement over the atomic spheres approximation and that the effect of the core hole can be limited to the photoabsorbing atom alone. Doping CaS with Eu will not affect the Ca and S K-edge XANES of CaS significantly but may give rise to a pre-edge structure not present for clean CaS., Comment: 7 pages, 5 figures

Published

2018

42. A topological material in the III-V family: heteroepitaxial InBi on InAs

Author

Nicolaï, Laurent, Minár, Ján, Richter, Maria Christine, Djukic, Uros, Heckmann, Olivier, Mariot, Jean-Michel, Adell, Johan, Leandersson, Mats, Sadowski, Janusz, Braun, Jürgen, Ebert, Hubert, Denlinger, Jonathan D., Vobornik, Ivana, Fujii, Jun, Šutta, Pavol, Bell, Gavin R., Gmitra, Martin, and Hricovini, Karol

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

InBi(001) is formed epitaxially on InAs(111)-A by depositing Bi on to an In-rich surface. Angle-resolved photoemission measurements reveal topological electronic surface states, close to the M bar high symmetry point. This demonstrates a heteroepitaxial system entirely in the III-V family with topological electronic properties. InBi shows coexistence of Bi and In surface terminations, in contradiction with other III-V materials. For the Bi termination, the study gives a consistent physical picture of the topological surface electronic structure of InBi(001) terminated by a Bi bilayer rather than a surface formed by splitting to a Bi monolayer termination. Theoretical calculations based on relativistic density functional theory and the one-step model of photoemission clarify the relationship between the InBi(001) surface termination and the topological surface states, supporting a predominant role of the Bi bilayer termination. Furthermore, a tight-binding model based on this Bi bilayer termination with only Bi-Bi hopping terms, and no Bi-In interaction, gives a deeper insight into the spin texture., Comment: 5 figures, 12 pages (+ Sup.)

Published

2018

43. Signature of a highly spin polarized resonance state at Co2MnSi(001)/Ag(001) interfaces

Author

Lidig, Christian, Minár, Jan, Braun, Jürgen, Ebert, Hubert, Gloskovskii, Andrei, Kronenberg, Alexander, Kläui, Mathias, and Jourdan, Martin

Subjects

Condensed Matter - Materials Science

Abstract

We investigated interfaces of halfmetallic Co2MnSi(100) Heusler thin films with Ag(100), Cr(100), Cu and Al layers relevant for spin valves by high energy x-ray photoemission spectroscopy (HAXPES). Experiments on Co2MnSi samples with an Ag(100) interface showed a characteristic spectral shoulder feature close to the Fermi edge, which is strongly diminished or suppressed at Co2MnSi (100) interfaces with the other metallic layers. This feature is found to be directly related to the Co2MnSi(100) layer, as reflected by control experiments with reference non-magnetic films, i.e. without Heusler layer. By comparison with HAXPES calculations, the shoulder feature is identified as originating from an interface state related to a highly spin polarized surface resonance of Co2MnSi (100)., Comment: 5 pages, 6 figures

Published

2018

44. Element- and momentum-resolved electronic structure of the dilute magnetic semiconductor manganese doped gallium arsenide

Author

Nemšák, Slavomír, Gehlmann, Mathias, Kuo, Cheng-Tai, Lin, Shih-Chieh, Schlueter, Christoph, Mlynczak, Ewa, Lee, Tien-Lin, Plucinski, Lukasz, Ebert, Hubert, Di Marco, Igor, Minár, Ján, Schneider, Claus M., and Fadley, Charles S.

Subjects

Condensed Matter - Materials Science

Abstract

The dilute magnetic semiconductors have promise in spin-based electronics applications due to their potential for ferromagnetic order at room temperature, and various unique switching and spin-dependent conductivity properties. However, the precise mechanism by which the transition-metal doping produces ferromagnetism has been controversial. Here we have studied a dilute magnetic semiconductor (5% manganese-doped gallium arsenide) with Bragg-reflection standing-wave hard X-ray angle-resolved photoemission spectroscopy, and resolved its electronic structure into element- and momentum- resolved components. The measured valence band intensities have been projected into element-resolved components using analogous energy scans of Ga 3d, Mn 2p, and As 3d core levels, with results in excellent agreement with element-projected Bloch spectral functions and clarification of the electronic structure of this prototypical material. This technique should be broadly applicable to other multi-element materials.

Published

2018

45. Electronic Structure of the Dilute Magnetic Semiconductor $Ga_{1-x}Mn_xP$ from Hard X-ray Photoelectron Spectroscopy and Hard X-ray Angle-Resolved Photoemission

Author

Keqi, Armela, Gehlmann, Mathias, Conti, Giuseppina, Nemšák, Slavomir, Rattanachata, Arunothai, Minár, Jan, Plucinski, Lukasz, Rault, Julien E, Rueff, Jean-Pascal, Scarpulla, Mike, Hategan, Mihael, Pálsson, Gunnar K, Conlon, Catherine, Eiteneer, Daria, Saw, Alexander Y, Gray, Alexander X, Kobayashi, Keisuke, Ueda, Shigenori, Dubon, Oscar D, Schneider, Claus M, and Fadley, Charles S

Subjects

Condensed Matter - Materials Science

Abstract

We have investigated the electronic structure of the dilute magnetic semiconductor (DMS) $Ga_{0.98}Mn_{0.02}P$ and compared it to that of an undoped $GaP$ reference sample, using hard X-ray photoelectron spectroscopy (HXPS) and hard X-ray angle-resolved photoemission spectroscopy (HARPES) at energies of about 3 keV. We present experimental data, as well as theoretical calculations, in order to understand the role of the Mn dopant in the emergence of ferromagnetism in this material. Both core-level spectra and angle-resolved or angle-integrated valence spectra are discussed. In particular, the HARPES experimental data are compared to free-electron final-state model calculations and to more accurate one-step photoemission theory. The experimental results show differences between $Ga_{0.98}Mn_{0.02}P$ and $GaP$ in both angle-resolved and angle-integrated valence spectra. The $Ga_{0.98}Mn_{0.02}P$ bands are broadened due to the presence of Mn impurities that disturb the long-range translational order of the host $GaP$ crystal. Mn-induced changes of the electronic structure are observed over the entire valence band range, including the presence of a distinct impurity band close to the valence-band maximum of the DMS. These experimental results are in good agreement with the one-step photoemission calculations, and a prior HARPES study of $Ga_{0.97}Mn_{0.03}As$ and $GaAs$ (Gray et al. Nature Materials 11, 957 (2012)), demonstrating the strong similarity between these two materials. The Mn 2p and 3s core-level spectra also reveal an essentially identical state in doping both $GaAs$ and $GaP$., Comment: 37 pages (double spaced) 10 figures

Published

2018

46. Finite lifetime broadening of calculated x-ray absorption spectra: possible artefacts close to the edge

Author

Sipr, Ondrej, Vackar, Jiri, and Minar, Jan

Subjects

Condensed Matter - Materials Science

Abstract

X-ray absorption spectra calculated within an effective one-electron approach have to be broadened to account for the finite lifetime of the core hole. For Green's function based methods this can be achieved either by adding a small imaginary part to the energy or by convoluting the spectra on the real axis with a Lorentzian. We demonstrate on the case of Fe K and L2,3 spectra that these procedures lead to identical results only for energies higher than few core level widths above the absorption edge. For energies close to the edge, spurious spectral features may appear if too much weight is put on broadening via the imaginary energy component. Special care should be taken for dichroic spectra at edges which comprise several exchange-split core levels, such as the L3 edge of 3d transition metals., Comment: 6 pages, 4 figures, 2 tables

Published

2017

47. Observation of a remarkable reduction of correlation effects in BaCr2As2 by ARPES

Author

Nayak, Jayita, Filsinger, Kai, Fecher, Gerhard H., Chadov, Stanislav, Minar, Jan, Rienks, Emile E. D., Buchner, Bernd, Fink, Jorg, and Felser, Claudia

Subjects

Condensed Matter - Materials Science

Abstract

The superconducting phase in iron based high Tc superconductors (FeSC) as in other unconventional superconductors such as the cuprates neighbours a magnetically ordered one in the phase diagram. This proximity hints at the importance of electron correlation effects in these materials, and Hund exchange interaction has been suggested to be the dominant correlation effect in FeSCs because of their multiband nature. By this reasoning, correlation should be strongest for materials closest to a half filled 3d shell (Mn compounds, hole doped FeSCs) and decrease for systems with both higher (electron doped FeSCs) and lower (Cr pnictides) 3d counts. Here we address the strength of correlation effects in BaCr2As2 by means of angle resolved photoelectron spectroscopy (ARPES) and first principles calculations. This combination provides us with two handles on the strength of correlation, First, a comparison of the experimental and calculated effective masses yields the correlation induced mass renormalisation. In addition, the lifetime broadening of the experimentally observed dispersions provides another measure of the correlation strength. Both approaches reveal a reduction of electron correlation in BaCr2As2 with respect to systems with a 3d count closer to five. Our results thereby support the theoretical predictions that Hund's exchange interaction is important in these materials., Comment: 15 pages, 4 figures

Published

2017

48. Interplay between disorder and electronic correlations in compositionally complex alloys.

Author

Redka, David, Khan, Saleem Ayaz, Martino, Edoardo, Mettan, Xavier, Ciric, Luka, Tolj, Davor, Ivšić, Trpimir, Held, Andreas, Caputo, Marco, Guedes, Eduardo Bonini, Strocov, Vladimir N., Di Marco, Igor, Ebert, Hubert, Huber, Heinz P., Dil, J. Hugo, Forró, László, and Minár, Ján

Subjects

PHOTOELECTRON spectroscopy, OPTICAL conductivity, DENSITY functional theory, ELECTRICAL resistivity, OPTICAL measurements, PHOTOEMISSION

Abstract

Owing to their exceptional mechanical, electronic, and phononic transport properties, compositionally complex alloys, including high-entropy alloys, represent an important class of materials. However, the interplay between chemical disorder and electronic correlations, and its influence on electronic structure-derived properties, remains largely unexplored. This is addressed for the archetypal CrMnFeCoNi alloy using resonant and valence band photoemission spectroscopy, electrical resistivity, and optical conductivity measurements, complemented by linear response calculations based on density functional theory. Utilizing dynamical mean-field theory, correlation signatures and damping in the spectra are identified, highlighting the significance of many-body effects, particularly in states distant from the Fermi edge. Electronic transport remains dominated by disorder and potentially short-range order, especially at low temperatures, while visible-spectrum optical conductivity and high-temperature transport are influenced by short quasiparticle lifetimes. These findings improve our understanding of element-specific electronic correlations in compositionally complex alloys and facilitate the development of advanced materials with tailored electronic properties. Compositionally complex alloys have attracted significant attention recently, but the role of electronic correlations in these materials is unknown. Redka et al. study the CrMnFeCoNi alloy using a combination of experimental and theoretical techniques, revealing strong correlation effects far from the Fermi edge. [ABSTRACT FROM AUTHOR]

Published

2024

49. Vectorial spin-polarization detection in multichannel spin-resolved photoemission spectroscopy using an Ir(001) imaging spin filter

Author

Schaefer, Erik D., Borek, Stephan, Braun, Jürgen, Minár, Ján, Ebert, Hubert, Medjanik, Katerina, Schönhense, Gerd, and Elmers, Hans-Joachim

Subjects

Physics - Instrumentation and Detectors

Abstract

We report on spin- and angular resolved photoemission spectroscopy using a high-resolution imaging spin filter based on a large Ir(001) crystal enhancing the effective figure of merit for spin detection by a factor of over $10^3$ compared to standard single channel detectors. Furthermore, we review the spin filter preparation, and its lifetime. The spin filter efficiency is mapped on a broad range of scattering energies and azimuthal angles. Large spin filter efficiencies are observed for the spin component perpendicular as well as parallel to the scattering plane depending on the azimuthal orientation of the spin filter crystal. A spin rotator capable of manipulating the spin direction prior to detection complements the measurement of three observables, thus allowing for a derivation of all three components of the spin polarization vector in multichannel spin polarimetry. The experimental results nicely agree with spin-polarized low energy electron diffraction calculations based on a fully relativistic multiple scattering method in the framework of spin-polarized density functional theory.

Published

2016

50. Analyzing core level photoelectrons by diffraction and circular dichroism via means of first-principle scattering calculations.

Author

Vo, Trung-Phuc, Tkach, Olena, Tricot, Sylvain, Sébilleau, Didier, Winkelmann, Aimo, Fedchenko, Olena, Lytvynenko, Yaryna, Vasilyev, Dmitry, Elmers, Hans-Joachim, Schönhense, Gerd, and Minár, Ján

Subjects

ATOMIC structure, HARD X-rays, CIRCULAR dichroism, PHOTOELECTRONS, ELECTRONIC structure, PHOTOEMISSION

Abstract

Photoelectron diffraction (PED) of core-level photoemission is an influential spectroscopic technique that provides valuable insights into the electronic and geometrical structure of materials at the atomic scale. In fact, it is not only a powerful method but also an unexpected effect. The choice of an appropriate theoretical formalism to interpret the experiments is therefore a necessity. Building on our previous successful work on the implementation of PED under the SPRKKR package, this study presents new and detailed experimental-theoretical comparisons of other core levels, providing deeper insights into material properties. We have calculated the circular dichroism in angular distributions (CDAD) for 3p, 3d and 4p of W(110) for application-specific purposes. The discriminant diffractogram between split core-levels is discussed. Above 50% difference in the spin-orbit doublets of 3d and 4p is reported. Hard X-rays (6000 eV) with right and left circularly polarized radiation (RCP and LCP, respectively) are used to generate photoelectrons. Through a comprehensive comparison of measured and calculated results, this study advances our understanding of PED simulations and their implications for materials characterization and discovery. [ABSTRACT FROM AUTHOR]

Published

2024