Your search keyword '"von Rohr, F. O."' showing total 23 results

1. Bonding states underpinning structural transitions in IrTe$_2$ observed with micro-ARPES

Author

Nicholson, C. W., Watson, M. D., Pulkkinen, A., Rumo, M., Kremer, G., Ma, K. Y., von Rohr, F. O., Cacho, C., and Monney, C.

Subjects

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

Abstract

Competing interactions in low-dimensional materials can produce nearly degenerate electronic and structural phases. We investigate the staircase of structural phase transitions in layered IrTe$_2$ for which a number of potential transition mechanisms have been postulated. The spatial coexistence of multiple phases on the micron scale has prevented a detailed analysis of the electronic structure. By exploiting micro-ARPES obtained with synchrotron radiation we extract the electronic structure of the multiple structural phases in IrTe$_2$ in order to address the mechanism underlying the phase transitions. We find direct evidence of lowered energy states that appear in the low-temperature phases, states previously predicted by \textit{ab initio} calculations and extended here. Our results validate a proposed scenario of bonding and anti-bonding states as the driver of the phase transitions., Comment: None

Published

2024

2. Anomalous Shubnikov-de Haas effect and observation of the Bloch-Gr\'uneisen temperature in the Dirac semimetal ZrTe5

Author

Galeski, S., Araki, K., Forslund, O. K., Wawrzynczak, R., Legg, H. F., Sivakumar, P. K., Miniotaite, U., Elson, F., Månsson, M., Witteveen, C., von Rohr, F. O., Baron, A. Q. R., Ishikawa, D., Li, Q., Gu, G., Zhao, L. X., Zhu, W. L., Chen, G. F., Wang, Y., Parkin, S. S. P., Gorbunov, D., Zherlitsyn, S., Vlaar, B., Nguyen, D. H., Paschen, S., Narang, P., Felser, C., Wosnitza, J., Meng, T., Sassa, Y., Hartnoll, S. A., and Gooth, J.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Quantum Gases

Abstract

Appearance of quantum oscillations (QO) in both thermodynamic and transport properties of metals at low temperatures is the most striking experimental consequence of the existence of a Fermi surface (FS). The frequency of these oscillations and the temperature dependence of their amplitude provides essential information about the FS topology and fermionic quasiparticle properties. Here, we report the observation of an anomalous suppression of the QO amplitude seen in resistivity (Shubnikov de-Haas effect) at sub-kelvin temperatures in ZrTe5 samples with a single small FS sheet comprising less than 5% of the first Brillouin zone. By comparing these results with measurements of the magneto-acoustic QO and the recovery of the usual Lifshitz-Kosevich behavior of the Shubnikov de-Haas (SdH) effect in ZrTe$_5$ samples with a multi-sheet FS, we show that the suppression of the SdH effect originates from a decoupling of the electron liquid from the lattice. On crossing the so-called Bloch-Gr\"uneisen temperature, T$_BG$, electron-phonon scattering becomes strongly suppressed and in the absence of Umklapp scattering the electronic liquid regains Galilean invariance. In addition, we show, using a combination of zero-field electrical conductivity and ultrasonic-absorption measurements, that entering this regime leads to an abrupt increase of electronic viscosity.

Published

2023

3. The Duel of Magnetic Interactions & Structural Instabilities: Itinerant Frustration in the Triangular Lattice Compound LiCrSe$_2$

Author

Nocerino, E., Kobayashi, S., Witteveen, C., Forslund, O. K., Matsubara, N., Tang, C., Matsukawa, T., Hoshikawa, A., Koda, A., Yoshimura, K., Umegaki, I., Sassa, Y., von Rohr, F. O., Pomjakushin, V., Brewer, J. H., Sugiyama, J., and Månsson, M.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The recent synthesis of the chromium selenide compound LiCrSe$_2$ constitutes a valuable addition to the ensemble of two-dimensional triangular lattice antiferromagnets (2D-TLA). In this work we present the very first comprehensive study of the combined low temperature nuclear and magnetic structure established in this material. Details on the connection between Li-ion dynamics and structural changes are also presented along with a direct link between atomic structure and spin order via a strong magnetoelastic coupling. LiCrSe$_2$ was found to undergo a first order structural transition from a trigonal crystal system with space group $P\bar{3}m1$ to a monoclinic one with space group $C2/m$ at $T_{\rm s}=30$~K. Such restructuring of the lattice is accompanied by a magnetic transition at $T_{\rm N}=30$~K, with the formation of a complex spin arrangement for the Cr$^{3+}$ moments. Refinement of the magnetic structure with neutron diffraction data and complementary muon spin rotation analysis reveal the presence of two incommensurate magnetic domains with a up-up-down-down arrangement of the spins with ferromagnetic (FM) double chains coupled antiferromagnetically (AFM). In addition to this unusual arrangement, the spin axial vector is modulated both in direction and modulus, resulting in a spin density wave-like order with periodic suppression of the Cr moment along the chains. This behavior is believed to appear as a result of strong competition between direct exchange AFM and superexchange FM couplings established between both nearest neighbor and next nearest neighbor Cr$^{3+}$ ions. We finally conjecture that the resulting magnetic order is stabilized via subtle vacancy/charge order within the Li layers, potentially causing a mix of two different magnetic phases within the sample.

Published

2022

4. Nuclear and magnetic spin structure of the antiferromagnetic triangular lattice compound LiCrTe$_2$ investigated by $\mu^+$SR as well as neutron and X-ray diffraction

Author

Nocerino, E., Witteveen, C., Kobayashi, S., Forslund, O. K., Matsubara, N., Zubayer, A., Mazza, F., Kawaguchi, S., Hoshikawa, A., Umegaki, I., Sugiyama, J., Yoshimura, K., Sassa, Y., von Rohr, F. O., and Månsson, M.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Two$-$dimensional (2D) triangular lattices antiferromagnets (2D$-$TLA) often manifest intriguing physical and technological properties, due to the strong interplay between lattice geometry and electronic properties. The recently synthesized 2$-$dimensional transition metal dichalcogenide LiCrTe$_2$, being a 2D$-$TLA, enriched the range of materials which can present such properties. In this work, muon spin rotation ($\mu^+$SR) and neutron powder diffraction (NPD) have been utilized to reveal the true magnetic nature and ground state of LiCrTe$_2$. From high$-$resolution NPD the magnetic spin order at base$-$temperature is not, as previously suggested, helical, but rather collinear antiferromagnetic (AFM) with ferromagnetic (FM) spin coupling within the $ab-$plane and AFM coupling along the $c-$axis. The ordered magnetic Cr moment is established as $\mu_{\rm Cr}=$ 2.36 $\mu_{\rm B}$. From detailed $\mu^+$SR measurements we observe an AFM ordering temperature $T_{\rm N}\approx$ 125 K. This value is remarkably higher than the one previously reported by magnetic bulk measurements. From $\mu^+$SR we are able to extract the magnetic order parameter, whose critical exponent allows us to categorize LiCrTe$_2$ in the 3D Heisenberg AFM universality class. Finally, by combining our magnetic studies with high$-$resolution synchrotron X$-$ray diffraction (XRD), we find a clear coupling between the nuclear and magnetic spin lattices. This suggests the possibility for a strong magnon$-$phonon coupling, similar to what has been previously observed in the closely related compound LiCrO$_2$.

Published

2022

5. Insensitivity of the striped charge-orders in IrTe$_2$ to alkali surface doping implies their structural origin

Author

Rumo, M., Pulkkinen, A., Salzmann, B., Kremer, G., Hildebrand, B., Ma, K. Y., von Rohr, F. O., Nicholson, C. W., Jaouen, T., and Monney, C.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We present a combined angle-resolved photoemission spectroscopy and low-energy electron diffraction (LEED) study of the prominent transition metal dichalcogenide IrTe$_2$ upon potassium (K) deposition on its surface. Pristine IrTe$_2$ undergoes a series of charge-ordered phase transitions below room temperature that are characterized by the formation of stripes of Ir dimers of different periodicities. Supported by density functional theory calculations, we first show that the K atoms dope the topmost IrTe$_2$ layer with electrons, therefore strongly decreasing the work function and shifting only the electronic surface states towards higher binding energy. We then follow the evolution of its electronic structure as a function of temperature across the charge-ordered phase transitions and observe that their critical temperatures are unchanged for K coverages of $0.13$ and $0.21$~monolayer (ML). Using LEED, we also confirm that the periodicity of the related stripe phases is unaffected by the K doping. We surmise that the charge-ordered phase transitions of IrTe$_2$ are robust against electron surface doping, because of its metallic nature at all temperatures, and due to the importance of structural effects in stabilizing charge order in IrTe$_2$.

Published

2021

6. Ultrafast Dynamics of the Surface Photovoltage in Potassium Doped Black Phosphorus

Author

Kremer, G., Rumo, M., Yue, C., Pulkkinen, A., Nicholson, C. W., Jaouen, T., von Rohr, F. O., Werner, P., and Monney, C.

Subjects

Condensed Matter - Materials Science

Abstract

Black phosphorus is a quasi-two-dimensional layered semiconductor with a narrow direct band gap of 0.3 eV. A giant surface Stark effect can be produced by the potassium doping of black phosphorus, leading to a semiconductor to semimetal phase transition originating from the creation of a strong surface dipole and associated band bending. By using time- and angle-resolved photoemission spectroscopy, we report the partial photoinduced screening of this band bending by the creation of a compensating surface photovoltage. We further resolve the detailed dynamics of this effect at the pertinent timescales and the related evolution of the band structure near the Fermi level. We demonstrate that after a fast rise time, the surface photovoltage exhibits a plateau over a few tens of picoseconds before decaying on the nanosecond timescale. We support our experimental results with simulations based on drift-diffusion equations., Comment: 18 pages, 12 figures

Published

2021

7. Observation of a uniaxial strain-induced phase transition in the 2D topological semimetal IrTe$_2$

Author

Nicholson, C. W., Rumo, M., Pulkkinen, A., Kremer, G., Salzmann, B., Mottas, M. -L., Hildebrand, B., Jaouen, T., Kim, T. K., Mukherjee, S., Ma, K. Y., Muntwiler, M., von Rohr, F. O., Cacho, C., and Monney, C.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Strain is ubiquitous in solid-state materials, but despite its fundamental importance and technological relevance, leveraging externally applied strain to gain control over material properties is still in its infancy. In particular, strain control over the diverse phase transitions and topological states in two-dimensional (2D) transition metal dichalcogenides (TMDs) remains an open challenge. Here, we exploit uniaxial strain to stabilize the long-debated structural ground state of the 2D topological semimetal IrTe$_2$, which is hidden in unstrained samples. Combined angle-resolved photoemission spectroscopy (ARPES) and scanning tunneling microscopy (STM) data reveal the strain-stabilized phase has a 6x1 periodicity and undergoes a Lifshitz transition, granting unprecedented spectroscopic access to previously inaccessible type-II topological Dirac states that dominate the modified inter-layer hopping. Supported by density functional theory (DFT) calculations, we show that strain induces a charge transfer strongly weakening the inter-layer Te bonds and thus reshaping the energetic landscape of the system in favor of the 6x1 phase. Our results highlight the potential to exploit strain-engineered properties in layered materials, particularly in the context of tuning inter-layer behavior., Comment: Main article: 9 pages, 4 figures; Methods: 3 pages; Supplementary: 8 pages, 7 figures, 1 table

Published

2021

8. Pressure induced topological quantum phase transition in Weyl semimetal T_d-MoTe_2

Author

Guguchia, Z., Santos, A. M. dos, von Rohr, F. O., Molaison, J. J., Banerjee, S., Rhodes, D., Yin, J. -X., Khasanov, R., Hone, J., Uemura, Y. J., Hasan, M. -Z., Luetkens, H., Bozin, E. S., and Amato, A.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Superconductivity

Abstract

We report the pressure (p_max = 1.5 GPa) evolution of the crystal structure of the Weyl semimetal T_d-MoTe_2 by means of neutron diffraction experiments. We find that the fundamental non-centrosymmetric structure T_d is fully suppressed and transforms into a centrosymmertic 1T' structure at a critical pressure of p_cr = 1.2 GPa. This is strong evidence for a pressure induced quantum phase transition (QPT) between topological to a trivial electronic state. Although the topological QPT has strong effect on magnetoresistance, it is interesting that the superconducting critical temperature T_c, the superfluid density, and the SC gap all change smoothly and continuously across p_cr and no sudden effects are seen concomitantly with the suppression of the T_d structure. This implies that the T_c, and thus the SC pairing strength, is unaffected by the topological QPT. However, the QPT requires the change in the SC gap symmetry from non-trivial s+- to a trivial s++ state, which we discuss in this work. Our systematic characterizations of the structure and superconducting properties associated with the topological QPT provide deep insight into the pressure induced phase diagram in this topological quantum material., Comment: 9 pages, 4 figures

Published

2020

9. Examining the surface phase diagram of IrTe$_2$ with photoemission

Author

Rumo, M., Nicholson, C. W., Pulkkinen, A., Hildebrand, B., Kremer, G., Salzmann, B., Mottas, M. -L., Ma, K. Y., Wong, E L., Man, M. K. L., Dani, K. M., Barbiellini, B., Muntwiller, M., Jaouen, T., von Rohr, F. O., and Monney, C.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

In the transition metal dichalcogenide IrTe$_2$, low-temperature charge-ordered phase transitions involving Ir dimers lead to the occurrence of stripe phases of different periodicities, and nearly degenerate energies. Bulk-sensitive measurements have shown that, upon cooling, IrTe$_2$ undergoes two such first-order transitions to $(5\times1\times5)$ and $(8\times1\times8)$ reconstructed phases at $T_{c_1}\sim 280$~K and $T_{c_2}\sim 180$~K, respectively. Here, using surface sensitive probes of the electronic structure of IrTe$_2$, we reveal the first-order phase transition at $T_{c_3}=165$~K to the $(6\times1)$ stripes phase, previously proposed to be the surface ground state. This is achieved by combining x-ray photoemission spectroscopy and angle-resolved photoemission spectroscopy, which give access to the evolution of stripe domains and a particular surface state, the energy of which is dependent on the Ir dimer length. By performing measurements over a full thermal cycle, we also report the complete hysteresis of all these phases.

Published

2019

10. Low-energy excitations in type-II Weyl semimetal Td-MoTe2 evidenced through optical conductivity

Author

Santos-Cottin, D., Martino, E., Mardele, F. Le, Witteveen, C., von Rohr, F. O., Homes, C. C., Rukelj, Z., and Akrap, Ana

Subjects

Condensed Matter - Materials Science

Abstract

Molybdenum ditelluride, MoTe2, is a versatile material where the topological phase can be readily tuned by manipulating the associated structural phase transition. The fine details of the band structure of MoTe2, key to understanding its topological properties, have proven difficult to disentangle experientially due to the multi-band character of the material. Through experimental optical conductivity spectra, we detect two strong low-energy interband transitions. Both are linked to excitations between spin-orbit split bands. The lowest interband transition shows a strong thermal shift, pointing to a chemical potential that dramatically decreases with temperature. With the help of ab initio calculations and a simple two-band model, we give qualitative and quantitative explanation of the main features in the temperature-dependent optical spectra up to 400 meV.

Published

2019

11. Nodeless Superconductivity and its Evolution with Pressure in the Layered Dirac Semimetal 2M-WS_2

Author

Guguchia, Z., Gawryluk, D., Brzezinska, M., Tsirkin, S. S., Khasanov, R., Pomjakushina, E., von Rohr, F. O., Verezhak, J., Hasan, M. Z., Neupert, T., Luetkens, H., and Amato, A.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Materials Science

Abstract

The interaction between superconductivity and band topology can lead to various unconventional superconducting (SC) states, and represents a new frontier in condensed matter physics research. Recently, the transition metal dichalcogenide (TMD) system 2M-WS2 has been identified as a Dirac semimetal exhibiting both superconductivity with the highest Tc = 8.5 K among all the TMD materials and topological surface states with a single Dirac cone. Here we report on muon spin rotation (muSR) and density functional theory studies of microscopic SC properties and the electronic structure in 2M-WS2 at ambient and under hydrostatic pressures (p_max = 1.9 GPa). The SC order parameter in 2M-WS2 is determined to have single-gap s-wave symmetry. We further show a strong negative pressure effect on Tc and on the SC gap. This may be partly caused by the pressure induced reduction of the size of the electron pocket around the Gamma-point, at which a band inversion appears up to the highest applied pressure. We also find that the superfluid density ns is very weakly affected by pressure. The absence of a strong pressure effect on the superfluid density and the absence of a correlation between ns and Tc in 2M-WS2, in contrast to the other SC TMDs Td-MoTe2 and 2H-NbSe2, is explained in terms of its location in the optimal (ambient pressure) and above the optimal (under pressure) superconducting regions of the phase diagram and its large distance to the other possible competing or cooperating orders. These results hint towards a complex nature of the superconductivity in TMDs, despite the observed s-wave order parameter., Comment: 9 pages, 5 Figures, Supplementary Information, containing the XRD and magnetization data, is available upon request

Published

2019

12. Linear Scaling of the Superfluid Density with the Critical Temperature in the Layered Superconductor 2H-NbSe_2

Author

von Rohr, F. O., Orain, J. -C., Khasanov, R., Shermadini, Z., Nikitin, A., Chang, J., Wieteska, A. R., Pasupathy, A. N., Hasan, M. Z., Amato, A., Luetkens, H., Uemura, Y. J., and Guguchia, Z.

Subjects

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

Abstract

We report on high-pressure (p_max = 2.1 GPa) muon spin rotation experiments probing the temperature-dependent magnetic penetration depth in the layered superconductor 2H-NbSe_2. Upon increasing the pressure, we observe a substantial increase of the superfluid density n_s, which we find to scale linearly with T_c. This linear scaling is considered a hallmark feature of unconventional superconductivity, especially in high-temperature cuprate superconductors. Our current results, along with our earlier findings on 1T'-MoTe_2 (Z. Guguchia et. al., Nature Communications 8, 1082 (2017)), demonstrate that this linear relation is also an intrinsic property of the superconductivity in transition metal dichalcogenides, whereas the ratio T_c/T_F is approximately a factor of 20 lower than the ratio observed in hole-doped cuprates. We, furthermore, find that the values of the superconducting gaps are insensitive to the suppression of the quasi-two-dimensional CDW state, indicating that the CDW ordering and the superconductivity in 2H-NbSe_2 are independent of each other., Comment: 9 pages, 4 Figures. This work builds on our earlier findings on 1T'-MoTe2, arXiv:1704.05185, and expands our findings to 2H-NbSe2

Published

2019

13. Gap collapse and flat band induced by uniaxial strain in 1T−TaS2

Author

Nicholson, C. W., primary, Petocchi, F., additional, Salzmann, B., additional, Witteveen, C., additional, Rumo, M., additional, Kremer, G., additional, Ivashko, O., additional, von Rohr, F. O., additional, Werner, P., additional, and Monney, C., additional

Published

2024

14. Nuclear and magnetic spin structure of the antiferromagnetic triangular lattice compound LiCrTe2 investigated by $$\mu ^+$$SR, neutron and X-ray diffraction

Author

Nocerino, E., primary, Witteveen, C., additional, Kobayashi, S., additional, Forslund, O. K., additional, Matsubara, N., additional, Zubayer, A., additional, Mazza, F., additional, Kawaguchi, S., additional, Hoshikawa, A., additional, Umegaki, I., additional, Sugiyama, J., additional, Yoshimura, K., additional, Sassa, Y., additional, von Rohr, F. O., additional, and Månsson, M., additional

Published

2022

15. Nuclear and magnetic spin structure of the antiferromagnetic triangular lattice compound LiCrTe2 investigated by mu+SR, neutron and X-ray diffraction

Author

Nocerino, E., Witteveen, C., Kobayashi, S., Forslund, O. K., Matsubara, N., Zubayer, Anton, Mazza, F., Kawaguchi, S., Hoshikawa, A., Umegaki, I., Sugiyama, J., Yoshimura, K., Sassa, Y., von Rohr, F. O., Mansson, M., Nocerino, E., Witteveen, C., Kobayashi, S., Forslund, O. K., Matsubara, N., Zubayer, Anton, Mazza, F., Kawaguchi, S., Hoshikawa, A., Umegaki, I., Sugiyama, J., Yoshimura, K., Sassa, Y., von Rohr, F. O., and Mansson, M.

Abstract

Two-dimensional (2D) triangular lattice antiferromagnets (2D-TLA) often manifest intriguing physical and technological properties, due to the strong interplay between lattice geometry and electronic properties. The recently synthesized 2-dimensional transition metal dichalcogenide LiCrTe2, being a 2D-TLA, enriched the range of materials which can present such properties. In this work, muon spin rotation (mu+SR) and neutron powder diffraction (NPD) have been utilized to reveal the true magnetic nature and ground state of LiCrTe2. From high-resolution NPD the magnetic spin order at base-temperature is not, as previously suggested, helical, but rather collinear antiferromagnetic (AFM) with ferromagnetic (FM) spin coupling within the ab-plane and AFM coupling along the c-axis. The value if the ordered magnetic Cr moment is established as mu(Cr)=2.36 mu(B). From detailed mu+SR measurements we observe an AFM ordering temperature TN approximate to 125 K. This value is remarkably higher than the one previously reported by magnetic bulk measurements. From mu+SR we are able to extract the magnetic order parameter, whose critical exponent allows us to categorize LiCrTe2 in the 3D Heisenberg AFM universality class. Finally, by combining our magnetic studies with high-resolution synchrotron X-ray diffraction (XRD), we find a clear coupling between the nuclear and magnetic spin lattices. This suggests the possibility for a strong magnon-phonon coupling, similar to what has been previously observed in the closely related compound LiCrO2., Funding Agencies|Swedish Foundation for Strategic Research (SSF) within the Swedish national graduate school in neutron scattering (SwedNess); Swedish Research Council VR [2021-06157, 2017-05078]; Carl Tryggers Foundation for Scientific Research [CTS-18:272]; Japan Society for the Promotion Science (JSPS) KAKENHI [JP18H01863, JP20K21149]; Chalmers Area of Advance-Materials Science; JSPS KAKENHI [18KK0150]; Swiss National Science Foundation [PCEFP2-194183]; Swiss National Science Foundation (SNF) [PCEFP2_194183] Funding Source: Swiss National Science Foundation (SNF)

Published

2022

16. Ultrafast dynamics of the surface photovoltage in potassium-doped black phosphorus

Author

Kremer, G., primary, Rumo, M., additional, Yue, C., additional, Pulkkinen, A., additional, Nicholson, C. W., additional, Jaouen, T., additional, von Rohr, F. O., additional, Werner, P., additional, and Monney, C., additional

Published

2021

17. Insensitivity of the striped charge orders in IrTe2 to alkali surface doping implies their structural origin

Author

Rumo, M., primary, Pulkkinen, A., additional, Salzmann, B., additional, Kremer, G., additional, Hildebrand, B., additional, Ma, K. Y., additional, von Rohr, F. O., additional, Nicholson, C. W., additional, Jaouen, T., additional, and Monney, C., additional

Published

2021

18. Low-energy excitations in type-II Weyl semimetal Td -MoTe2 evidenced through optical conductivity

Author

Santos-Cottin, D., Martino, E., Mardele, F. Le, Witteveen, C., von Rohr, F. O., Homes, C. C., Rukelj, Z., and Akrap, Ana

Subjects

PRIRODNE ZNANOSTI. Fizika, Condensed Matter - Materials Science, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, NATURAL SCIENCES. Physics

Abstract

Molybdenum ditelluride, MoTe2, is a versatile material where the topological phase can be readily tuned by manipulating the associated structural phase transition. The fine details of the band structure of MoTe2, key to understanding its topological properties, have proven difficult to disentangle experientially due to the multi-band character of the material. Through experimental optical conductivity spectra, we detect two strong low-energy interband transitions. Both are linked to excitations between spin-orbit split bands. The lowest interband transition shows a strong thermal shift, pointing to a chemical potential that dramatically decreases with temperature. With the help of ab initio calculations and a simple two-band model, we give qualitative and quantitative explanation of the main features in the temperature-dependent optical spectra up to 400 meV.

Published

2020

19. Examining the surface phase diagram of IrTe2 with photoemission

Author

Rumo, M., primary, Nicholson, C. W., additional, Pulkkinen, A., additional, Hildebrand, B., additional, Kremer, G., additional, Salzmann, B., additional, Mottas, M.-L., additional, Ma, K. Y., additional, Wong, E. L., additional, Man, M. K. L., additional, Dani, K. M., additional, Barbiellini, B., additional, Muntwiler, M., additional, Jaouen, T., additional, von Rohr, F. O., additional, and Monney, C., additional

Published

2020

20. Low-energy excitations in type-II Weyl semimetal Td−MoTe2 evidenced through optical conductivity

Author

Santos-Cottin, D., primary, Martino, E., additional, Le Mardelé, F., additional, Witteveen, C., additional, von Rohr, F. O., additional, Homes, C. C., additional, Rukelj, Z., additional, and Akrap, Ana, additional

Published

2020

21. Unconventional scaling of the superfluid density with the critical temperature in transition metal dichalcogenides

Author

von Rohr, F. O., Orain, J.-C., Khasanov, R., Witteveen, C., Shermadini, Z., Nikitin, A., Chang, J., Wieteska, A. R., Pasupathy, A. N., Hasan, M. Z., Amato, A., Luetkens, H., Uemura, Y. J., Guguchia, Z., University of Zurich, and Guguchia, Z

Subjects

10120 Department of Chemistry, 1000 Multidisciplinary, 530 Physics, Materials Science, SciAdv r-articles, 10192 Physics Institute, Condensed Matter Physics, Quantitative Biology::Cell Behavior, Computer Science::Emerging Technologies, Condensed Matter::Superconductivity, Computer Science::General Literature, Condensed Matter::Strongly Correlated Electrons, 3101 Physics and Astronomy (miscellaneous), Research Articles, Research Article

Abstract

Pressure effect in NbSe2 resembles hallmark features of unconventional superconductivity in cuprates., We report on muon spin rotation experiments probing the magnetic penetration depth λ(T) in the layered superconductors in 2H-NbSe2 and 4H-NbSe2. The current results, along with our earlier findings on 1T′-MoTe2 (Guguchia et al.), demonstrate that the superfluid density scales linearly with Tc in the three transition metal dichalcogenide superconductors. Upon increasing pressure, we observe a substantial increase of the superfluid density in 2H-NbSe2, which we find to correlate with Tc. The correlation deviates from the abovementioned linear trend. A similar deviation from the Uemura line was also observed in previous pressure studies of optimally doped cuprates. This correlation between the superfluid density and Tc is considered a hallmark feature of unconventional superconductivity. Here, we show that this correlation is an intrinsic property of the superconductivity in transition metal dichalcogenides, whereas the ratio Tc/TF is approximately a factor of 20 lower than the ratio observed in hole-doped cuprates. We, furthermore, find that the values of the superconducting gaps are insensitive to the suppression of the charge density wave state.

Published

2019

22. Unconventional scaling of the superfluid density with the critical temperature in transition metal dichalcogenides

Author

von Rohr, F. O., primary, Orain, J.-C., additional, Khasanov, R., additional, Witteveen, C., additional, Shermadini, Z., additional, Nikitin, A., additional, Chang, J., additional, Wieteska, A. R., additional, Pasupathy, A. N., additional, Hasan, M. Z., additional, Amato, A., additional, Luetkens, H., additional, Uemura, Y. J., additional, and Guguchia, Z., additional

Published

2019

23. Low-energy excitations in type-II Weyl semimetal T-d-MoTe2 evidenced through optical conductivity

Author

Santos-Cottin, D., Martino, E., Le Mardele, F., Witteveen, C., von Rohr, F. O., Homes, C. C., Rukelj, Z., and Akrap, Ana

Subjects

resistivity, mote2, transistors

Abstract

Molybdenum ditelluride, MoTe2, is a versatile material where the topological phase can be readily tuned by manipulating the associated structural phase transition. The fine details of the band structure of MoTe2, key to understanding its topological properties, have proven difficult to disentangle experientially due to the multiband character of the material. Through experimental optical conductivity spectra, we detect two strong low-energy interband transitions. Both are linked to excitations between spin-orbit split bands. The lowest interband transition shows a strong thermal shift, pointing to a chemical potential that dramatically decreases with temperature. With the help of ab initio calculations and a simple two-band model, we give qualitative and quantitative explanations of the main features in the temperature-dependent optical spectra up to 400 meV.