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1. Excitonic response in TMD heterostructures from first-principles: impact of stacking, twisting, and interlayer distance

Author

Reho, R., Botello-Méndez, A. R., Sangalli, D., Verstraete, M. J., and Zanolli, Zeila

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Van der Waals heterostructures of two-dimensional transition metal dichalcogenides provide a unique platform to engineer optoelectronic devices tuning their optical properties via stacking, twisting, or straining. Using ab initio Many-Body Perturbation Theory, we predict the electronic and optical (absorption and photoluminescence spectra) properties of MoS$_2$/WS$_2$ and MoSe$_2$/WSe$_2$ hetero-bilayers with different stacking and twisting. We analyse the valley splitting and optical transitions, and explain the enhancement or quenching of the inter- and intra-layer exciton states. Contrary to established models, that focus on transitions near the high-symmetry point K, our results include all possible transitions across the Brillouin Zone. This result, for a twisted Se-based heterostructures, in an interlayer exciton with significant electron density in both layers and a mixed intralayer exciton distributed over both MoSe$_2$ and WSe$_2$. We propose that it should be possible to produce an inverted order of the excitonic states in some MoSe$_2$/WSe$_2$ heterostructures, where the energy of the intralayer WSe$_2$ exciton is lower than that in MoSe$_2$. We predict the variability of the exciton peak positions ($\sim$100 meV) and the exciton radiative lifetimes, from pico- to nano-seconds, and even micro-seconds in twisted bilayers. The control of exciton energies and lifetimes paves the way towards applications in quantum information technologies and optical sensing.

Published
2024

2. Investigation and field effect tuning of thermoelectric properties of SnSe2 flakes

Author

Pallecchi, I., Caglieris, F., Ceccardi, M., Manca, N., Marre', D., Repetto, L., Schott, M., Bilc, D. I., Chaitoglou, S., Dimoulas, A., and Verstraete, M. J.

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

The family of Van der Waals dichalcogenides (VdWDs) includes a large number of compositions and phases, exhibiting varied properties and functionalities. They have opened up a novel electronics of two-dimensional materials, characterized by higher integration and interfaces which are atomically sharper and cleaner than conventional electronics. Among these functionalities, some VdWDs possess remarkable thermoelectric properties. SnSe2 has been identified as a promising thermoelectric material on the basis of its estimated electronic and transport properties. In this work we carry out experimental meas-urements of the electric and thermoelectric properties of SnSe2 flakes. For a 30 micron thick SnSe2 flake at room temperature, we measure electron mobility of 40 cm^2 V^-1 s^-1, a carrier density of 4 x 10^18 cm^-3, a Seebeck coefficient S around -400 microV/K and thermoelectric power factor around 0.35 mW m^-1 K^-2. The comparison of experimental results with theoretical calculations shows fair agreement and indicates that the dominant carrier scattering mechanisms are polar optical phonons at room temperature and ionized im-purities below 50 K. In order to explore possible improvement of the thermoelectric properties, we carry out reversible electrostatic doping on a thinner flake, in a field effect setup. On this 75 nm thick SnSe2 flake, we measure a field effect variation of the Seebeck coefficient of up to 290 % at low temperature, and a corresponding variation of the thermoelectric power factor of up to 1050 %. We find that the power factor increases with the depletion of n-type charge carriers. Field effect control of thermoelectric transport opens perspectives for boosting energy harvesting and novel switching technologies based on two-dimensional materials., Comment: in press on Physical Review Materials

Published
2023
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3. Unraveling heat transport and dissipation in suspended MoSe$_2$ crystals from bulk to monolayer

Author

Reig, D. Saleta, Varghese, S., Farris, R., Block, A., Mehew, J. D., Hellman, O., Woźniak, P., Sledzinska, M., Sachat, A. El, Chávez-Ángel, E., Valenzuela, S. O., Van Hulst, N. F., Ordejón, P., Zanolli, Z., Torres, C. M. Sotomayor, Verstraete, M. J., and Tielrooij, K. J.

Subjects
Condensed Matter - Materials Science
Abstract

Understanding thermal transport in layered transition metal dichalcogenide (TMD) crystals is crucial for a myriad of applications exploiting these materials. Despite significant efforts, several basic thermal transport properties of TMDs are currently not well understood. Here, we present a combined experimental-theoretical study of the intrinsic lattice thermal conductivity of the representative TMD MoSe$_2$, focusing on the effect of material thickness and the material's environment. We use Raman thermometry measurements on suspended crystals, where we identify and eliminate crucial artefacts, and perform $ab$ $initio$ simulations with phonons at finite, rather than zero, temperature. We find that phonon dispersions and lifetimes change strongly with thickness, yet (sub)nanometer thin TMD films exhibit a similar in-plane thermal conductivity ($\sim$20~Wm$^{-1}$K$^{-1}$) as bulk crystals ($\sim$40~Wm$^{-1}$K$^{-1}$). This is the result of compensating phonon contributions, in particular low-frequency modes with a surprisingly long mean free path of several micrometers that contribute significantly to thermal transport for monolayers. We furthermore demonstrate that out-of-plane heat dissipation to air is remarkably efficient, in particular for the thinnest crystals. These results are crucial for the design of TMD-based applications in thermal management, thermoelectrics and (opto)electronics.

Published
2021

4. Bulk Electronic Structure of Lanthanum Hexaboride (LaB6) by Hard X-ray Angle-Resolved Photoelectron Spectroscopy

Author

Rattanachata, A., Nicolaï, L., Martins, H. P., Conti, G., Verstraete, M. J., Gehlmann, M., Ueda, S., Kobayashi, K., Vishik, I., Schneider, C. M., Fadley, C. S., Gray, A. X., Minár, J., and Nemšák, S.

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

In the last decade rare-earth hexaborides have been investigated for their fundamental importance in condensed matter physics, and for their applications in advanced technological fields. Among these compounds, LaB$_6$ has a special place, being a traditional d-band metal without additional f- bands. In this paper we investigate the bulk electronic structure of LaB$_6$ using hard x-ray photoemission spectroscopy, measuring both core-level and angle-resolved valence-band spectra. By comparing La 3d core level spectra to cluster model calculations, we identify well-screened peak residing 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 bulk-like band structure of LaB$_6$ determined by hard x-ray angle-resolved photoemission spectroscopy (HARPES). We interpret HARPES experimental results by the free-electron final-state calculations and by the more precise one-step photoemission theory including matrix element and phonon excitation effects. In addition, we consider the nature and the magnitude of phonon excitations in HARPES experimental data measured at different temperatures and excitation energies. We demonstrate that one step theory of photoemission and HARPES experiments provide, at present, the only approach capable of probing true bulk-like electronic band structure of rare-earth hexaborides and strongly correlated materials., Comment: Total 26 pages, Total 11 figures

Published
2020
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5. The PseudoDojo: Training and grading a 85 element optimized norm-conserving pseudopotential table

Author

van Setten, M. J., Giantomassi, M., Bousquet, E., Verstraete, M. J., Hamann, D. R., Gonze, X., and Rignanese, G. -M.

Subjects
Condensed Matter - Materials Science
Abstract

First-principles calculations in crystalline structures are often performed with a planewave basis set. To make the number of basis functions tractable two approximations are usually introduced: core electrons are frozen and the diverging Coulomb potential near the nucleus is replaced by a smoother expression. The norm-conserving pseudopotential was the first successful method to apply these approximations in a fully ab initio way. Later on, more efficient and more exact approaches were developed based on the ultrasoft and the projector augmented wave formalisms. These formalisms are however more complex and developing new features in these frameworks is usually more difficult than in the norm-conserving framework. Most of the existing tables of norm- conserving pseudopotentials, generated long ago, do not include the latest developments, are not systematically tested or are not designed primarily for high accuracy. In this paper, we present our PseudoDojo framework for developing and testing full tables of pseudopotentials, and demonstrate it with a new table generated with the ONCVPSP approach. The PseudoDojo is an open source project, building on the AbiPy package, for developing and systematically testing pseudopotentials. At present it contains 7 different batteries of tests executed with ABINIT, which are performed as a function of the energy cutoff. The results of these tests are then used to provide hints for the energy cutoff for actual production calculations. Our final set contains 141 pseudopotentials split into a standard and a stringent accuracy table. In total around 70.000 calculations were performed to test the pseudopotentials. The process of developing the final table led to new insights into the effects of both the core-valence partitioning and the non-linear core corrections on the stability, convergence, and transferability of norm-conserving pseudopotentials. ..., Comment: abstract truncated, 17 pages, 25 figures, 8 tables

Published
2017
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6. Localization of electrons and magnetization in fluoro-graphene: A DFT+U study

Author

Marsusi, F. and Verstraete, M. J.

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

Fluorine adatoms on graphene induce local changes in electronic and magnetic properties, and subtle correlation effects. We investigate the GGA and GGA+U approaches as possible solutions to describe the magnetic moment and electronic band structure of graphene sheets with fluorine adatoms, and compare to experiments. We show that, due to a lack of strong electronic correlations, GGA fails to reproduce the measured magnetic moment in this structure. In particular, the GGA incorrectly predicts a nonmagnetic ground state with a zero band gap. On the other hand, GGA+U is a computationally efficient tool which provides physically reasonable properties. Using Hubbard U and exchange J parameters of 5 eV and 0.1 eV provides a magnetic moment and optical gap in agreement with experiments. Our results imply that the magnetic moment observed in the experiment is injected by fluorine in carbon pz orbitals throughout the graphene sheet. The spin- orbit coupling (SOC) has almost no influence (ca. 2%) on the magnetism. No Rashba effect is detected and the magnetic moment induced by fluorine strongly dominates the electronic properties. Our findings explain the anisotropic magnetic behavior observed experimentally., Comment: 9 pages, 7 figures

Published
2017

7. Excitonic response in transition metal dichalcogenide heterostructures from first principles: Impact of stacking, twisting, and interlayer distance

Author

Reho, R., Botello-Mendez, A. R., Sangalli, D., Verstraete, M. J., Zanolli, Zeila, Reho, R., Botello-Mendez, A. R., Sangalli, D., Verstraete, M. J., and Zanolli, Zeila

Abstract

Van der Waals heterostructures of two-dimensional transition metal dichalcogenides provide a unique platform to engineer optoelectronic devices tuning their optical properties via stacking, twisting, or straining. Using ab initio many-body perturbation theory, we predict the electronic and optical (absorption and photoluminescence spectra) properties of MoS2/WS2 and MoSe2/WSe2 heterobilayers with different stacking and twisting. We analyze the valley splitting and optical transitions, and we explain the enhancement or quenching of the interand intralayer exciton states. We fully include transitions within the entire Brillouin Zone, contrary to predictions based on continuum models which only consider energies near the K point. As a result, we predict an interlayer exciton with significant electron density in both layers and a mixed intralayer exciton distributed over both MoSe2 and WSe2 in a twisted Se-based heterostructure. We propose that it should be possible to produce an inverted order of the excitonic states in some MoSe2/WSe2 heterostructures, where the energy of the intralayer WSe2 exciton is lower than that in MoSe2. We predict the variability across different stacking of the exciton peak positions (-100 meV) and the exciton radiative lifetimes, from pico- to nanoseconds, and even microseconds in twisted bilayers. The control of exciton energies and lifetimes paves the way toward applications in quantum information technologies and optical sensing.

Published
2024

8. Experimental determination of the temperature- and phase-dependent elastic constants of FeRh

Author

Ourdani, D., Castellano, A., Vythelingum, A. K., Arregi, J. A., Uhlir, V., Perrin, B., Belmeguenai, M., Roussigne, Y., Gourdon, C., Verstraete, M. J., Thevenard, L., Ourdani, D., Castellano, A., Vythelingum, A. K., Arregi, J. A., Uhlir, V., Perrin, B., Belmeguenai, M., Roussigne, Y., Gourdon, C., Verstraete, M. J., and Thevenard, L.

Abstract

The elastic constants of an epitaxial film of FeRh have been determined experimentally in both ferromagnetic (FM) and antiferromagnetic (AF) phases, using a combination of Brillouin light scattering and picosecond acoustics experiments. The C11 constant is noticeably larger in the FM phase than in the AF phase, while C12 and C44 are both lower, leading to larger Rayleigh wave velocities in the FM phase than in the AF phase. The elastic constants were calculated numerically using first-principles anharmonic modeling and machinelearned interatomic potentials. We find that using a temperature-dependent effective potential is indispensable to correctly reproduce the experimental values to within 80-100%. The accurate knowledge of the temperatureand phase-dependences of the elastic constants of crystalline FeRh are valuable ingredients for the predictive modeling of the acoustic and magnetoacoustic properties of this magnetostrictive material.

Published
2024

10. Cumulant expansion for phonon contributions to the electron spectral function

Author

Story, S. M., Kas, J. J., Vila, F. D., Verstraete, M. J., and Rehr, J. J.

Subjects
Condensed Matter - Materials Science
Abstract

We describe an approach for calculations of phonon contributions to the electron spectral function, including both quasiparticle properties and satellites. The method is based on a cumulant expansion for the retarded one-electron Green's function and a many-pole model for the electron self-energy. The electron-phonon couplings are calculated from the Eliashberg functions, and the phonon density of states is obtained from a Lanczos representation of the phonon Green's function. Our calculations incorporate ab initio dynamical matrices and electron-phonon couplings from the density functional theory code ABINIT. Illustrative results are presented for several elemental metals and for Einstein and Debye models with a range of coupling constants. These are compared with experiment and other theoretical models. Estimates of corrections to Migdal's theorem are obtained by comparing with leading order contributions to the self-energy, and are found to be significant only for large electron-phonon couplings at low temperatures.

Published
2014
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11. Thermal Anharmonic Effects in PbTe from First Principles

Author

Romero, A. H., Gross, E. K. U., Verstraete, M. J., and Hellman, Olle

Subjects
Condensed Matter - Materials Science
Abstract

We investigate the harmonic and anharmonic contributions to the phonon spectrum of lead telluride, and perform a complete characterization of how the anharmonic effects dominate the phonons in PbTe as temperature increases. This effect is the strongest factor in the favorable thermoelectric properties of PbTe: an optical-acoustic phonon band crossing reduces the speed of sound and the intrinsic thermal conductivity. We present the detailed temperature dependence of the dispersion relation and compare our calculated neutron scattering cross section with recent experimental measurements. We analyze the thermal resistivity's variation with temperature and clarify misconceptions about existing experimental literature. This quantitative prediction opens the way to phonon phase space engineering, to tailor the lifetimes of crucial heat carrying phonons.

Published
2014
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13. Doping-induced dimensional crossover and thermopower burst in Nb-doped SrTiO$_3$ superlattices

Author

Delugas, P., Filippetti, A., Verstraete, M. J., Pallecchi, I., Marré, D., and Fiorentini, V.

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

Using advanced ab-initio calculations, we describe the formation and confinement of a two-dimensional electron gas in short-period ($\simeq$4 nm) Nb-doped SrTiO$_3$ superlattices as function of Nb doping. We predict complete two-dimensional confinement for doping concentrations higher than 70%. In agreement with previous observations, we find a large thermopower enhancement at room temperature. However, this effect is primarily determined by dilution of the mobile charge over a multitude of weakly occupied bands. As a general rule, we conclude that thermopower in similar heterostructures will be more enhanced by weak, rathern than tight spatial confinement., Comment: 8 pages, 8 figures

Published
2013
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15. Functionality in single-molecule devices: Model calculations and applications of the inelastic electron tunneling signal in molecular junctions

Author

Dash, L. K., Ness, H., Verstraete, M. J., and Godby, R. W.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We analyze how functionality could be obtained within single-molecule devices by using a combination of non-equilibrium Green's functions and ab-initio calculations to study the inelastic transport properties of single-molecule junctions. First we apply a full non-equilibrium Green's function technique to a model system with electron-vibration coupling. We show that the features in the inelastic electron tunneling spectra (IETS) of the molecular junctions are virtually independent of the nature of the molecule-lead contacts. Since the contacts are not easily reproducible from one device to another, this is a very useful property. The IETS signal is much more robust versus modifications at the contacts and hence can be used to build functional nanodevices. Second, we consider a realistic model of a organic conjugated molecule. We use ab-initio calculations to study how the vibronic properties of the molecule can be controlled by an external electric field which acts as a gate voltage. The control, through the gate voltage, of the vibron frequencies and (more importantly) of the electron-vibron coupling enables the construction of functionality: non-linear amplification and/or switching is obtained from the IETS signal within a single-molecule device., Comment: Accepted for publication in Journal of Chemical Physics

Published
2012
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16. Density functional theory beyond the linear regime: Validating adiabatic LDA

Author

Helbig, N., Fuks, J. I., Casula, M., Verstraete, M. J., Marques, M. A. L., Tokatly, I. V., and Rubio, A.

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

We present a local density approximation (LDA) for one-dimensional (1D) systems interacting via the soft-Coulomb interaction based on quantum Monte-Carlo calculations. Results for the ground-state energies and ionization potentials of finite 1D systems show excellent agreement with exact calculations, obtained by exploiting the mapping of an $N$-electron system in $d$ dimensions, onto a single electron in $N\times d$ dimensions properly symmetrized by the Young diagrams. We conclude that 1D LDA is of the same quality as its three-dimensional (3D) counterpart, and we infer conclusions about 3D LDA. The linear and non-linear time-dependent responses of 1D model systems using LDA, exact exchange, and the exact solution are investigated and show very good agreement in both cases, except for the well known problem of missing double excitations. Consequently, the 3D LDA is expected to be of good quality beyond linear response. In addition, the 1D LDA should prove useful in modeling the interaction of atoms with strong laser fields, where this specific 1D model is often used., Comment: 5 pages, 3 figures

Published
2011
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17. Specification of an extensible and portable file format for electronic structure and crystallographic data

Author

Gonze, X., Almbladh, C. -O., Cucca, A., Caliste, D., Freysoldt, C., Marques, M. A. L., Olevano, V., Pouillon, Y., and Verstraete, M. J.

Subjects
Computer Science - Digital Libraries, Condensed Matter - Materials Science, Computer Science - Databases
Abstract

In order to allow different software applications, in constant evolution, to interact and exchange data, flexible file formats are needed. A file format specification for different types of content has been elaborated to allow communication of data for the software developed within the European Network of Excellence "NANOQUANTA", focusing on first-principles calculations of materials and nanosystems. It might be used by other software as well, and is described here in detail. The format relies on the NetCDF binary input/output library, already used in many different scientific communities, that provides flexibility as well as portability accross languages and platforms. Thanks to NetCDF, the content can be accessed by keywords, ensuring the file format is extensible and backward compatible.

Published
2008

22. Metal-insulator crossover in monolayer MoS2.

Author

Castillo, I, Sohier, T, Paillet, M, Cakiroglu, D, Consejo, C, Wen, C, Wasem Klein, F, Zhao, M-Q, Ouerghi, A, Contreras, S, Johnson, A T Charlie, Verstraete, M J, Jouault, B, and Nanot, S

Subjects
BOLTZMANN'S equation, ELECTRON gas, CARRIER density, OHMIC contacts, MONOMOLECULAR films, METAL-insulator transitions
Abstract

We report on transport measurements in monolayer MoS2 devices, close to the bottom of the conduction band edge. These devices were annealed in situ before electrical measurements. This allows us to obtain good ohmic contacts at low temperatures, and to measure precisely the conductivity and mobility via four-probe measurements. The measured effective mobility up to μ eff = 180 cm2 V−1 s−1 is among the largest obtained in CVD-grown MoS2 monolayer devices. These measurements show that electronic transport is of the insulating type for σ ≤ 1.4 e 2/ h and n ≤ 1.7 × 1012 cm−2, and a crossover to a metallic regime is observed above those values. In the insulating regime, thermally activated transport dominates at high temperature (T > 120 K). At lower temperatures, conductivity is driven by Efros–Schklovkii variable range hopping in all measured devices, with a universal and constant hopping prefactor, that is a clear indication that hopping is not phonon-mediated. At higher carrier density, and high temperature, the conductivity is well modeled by the Boltzmann equation for a non-interacting Fermi gas, taking into account both phonon and impurity scatterings. Finally, even if this apparent metal-insulator transition can be explained by phonon-related phenomena at high temperature, the possibility of a genuine 2D MIT cannot be ruled out, as we can observe a clear power-law diverging localization length close to the transition, and a one-parameter scaling can be realized. [ABSTRACT FROM AUTHOR]

Published
2023
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24. Surface phonons: Theoretical methods and results

Author

Benedek, G, Bernasconi, M, Campi, D, Toennies, J, Verstraete, M, Benedek G., Bernasconi M., Campi D., Toennies J. P., Verstraete M. J., Benedek, G, Bernasconi, M, Campi, D, Toennies, J, Verstraete, M, Benedek G., Bernasconi M., Campi D., Toennies J. P., and Verstraete M. J.

Abstract

The theoretical methods currently in use for the calculation of surface phononsurface phonon dispersion curves and how they have evolved from the phenomenological force-constant models to the present day first principles theories are discussed. A selection of paradigmatic examples for the different classes of crystal surfaces is presented with comparisons to the experimental data obtained from helium atom scattering or electron energy-loss spectroscopy.

Published
2020

29. Summary and Conclusions

Author

Verstraete, M. M., Menenti, M., Beniston, Martin, editor, Verstraete, Michel M., editor, Menenti, Massimo, editor, and Peltoniemi, Jouni, editor

Published
2000
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39. Bulk electronic structure of lanthanum hexaboride (LaB6) by hard x-ray angle-resolved photoelectron spectroscopy

Author

Rattanachata, A., Nicola��, L., Martins, H. P., Conti, G., Verstraete, M. J., Gehlmann, M., Ueda, S., Kobayashi, K., Vishik, I., Schneider, C. M., Fadley, C. S., Gray, A. X., Min��r, J., and Nem����k, S.

Subjects
Condensed Matter - Materials Science, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Applied Physics (physics.app-ph), Physics - Applied Physics, physics.app-ph, cond-mat.mtrl-sci
Abstract

In the last decade rare-earth hexaborides have been investigated for their fundamental importance in condensed matter physics, and for their applications in advanced technological fields. Among these compounds, LaB$_6$ has a special place, being a traditional d-band metal without additional f- bands. In this paper we investigate the bulk electronic structure of LaB$_6$ using hard x-ray photoemission spectroscopy, measuring both core-level and angle-resolved valence-band spectra. By comparing La 3d core level spectra to cluster model calculations, we identify well-screened peak residing 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 bulk-like band structure of LaB$_6$ determined by hard x-ray angle-resolved photoemission spectroscopy (HARPES). We interpret HARPES experimental results by the free-electron final-state calculations and by the more precise one-step photoemission theory including matrix element and phonon excitation effects. In addition, we consider the nature and the magnitude of phonon excitations in HARPES experimental data measured at different temperatures and excitation energies. We demonstrate that one step theory of photoemission and HARPES experiments provide, at present, the only approach capable of probing true bulk-like electronic band structure of rare-earth hexaborides and strongly correlated materials., Total 26 pages, Total 11 figures

Published
2021

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