Publications by authors named "Jasmin Jandke"
Spin-orbit coupling (SOC) is a fundamental physical interaction, which describes how the electrons' spin couples to their orbital motion. It is the source of a vast variety of fascinating phenomena in nanostructures. Although in most theoretical descriptions of high-temperature superconductivity SOC has been neglected, including this interaction can, in principle, revise the microscopic picture.
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- Nanoscale inhomogeneity significantly affects the properties of two-dimensional van der Waals materials, particularly in FeSeS where sulfur replaces selenium.
- This substitution leads to variations in Fe-Ch bond lengths and increases disorder when the sulfur concentration is between 0.4 and 0.8, which lowers the superconducting transition temperature.
- The high-temperature metallic resistivity surpasses the expected limits, indicating a new scattering mechanism linked to the disorder of Se/S atoms around iron, which may involve complex charge or magnetic behaviors.
Charge neutrality and their expected itinerant nature makes excitons potential transmitters of information. However, exciton mobility remains inaccessible to traditional optical experiments that only create and detect excitons with negligible momentum. Here, using angle-resolved photoemission spectroscopy, we detect dispersing excitons in the quasi-one-dimensional metallic trichalcogenide, TaSe.
View Article and Find Full Text PDFEmploying X-ray magnetic circular dichroism (XMCD), angle-resolved photoemission spectroscopy (ARPES), and momentum-resolved density fluctuation (MRDF) theory, the magnetic and electronic properties of ultrathin NdNiO (NNO) film in proximity to ferromagnetic (FM) La Sr MnO (LSMO) layer are investigated. The experimental data shows the direct magnetic coupling between the nickelate film and the manganite layer which causes an unusual ferromagnetic (FM) phase in NNO. Moreover, it is shown the metal-insulator transition in the NNO layer, identified by an abrupt suppression of ARPES spectral weight near the Fermi level (E ), is absent.
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- Parity-time symmetry is crucial for Dirac states in Dirac semimetals, but achieving magnetic Dirac semimetals has been challenging in research.* -
- This study combines angle-resolved photoemission spectroscopy and density functional theory, revealing that band inversion can create a topologically nontrivial state in EuCdAs, resulting in ideal magnetic Dirac fermions.* -
- Although the magnetic order breaks time reversal symmetry, it maintains inversion symmetry, leading to a new state featuring multiple topological insulator types, thus expanding the potential for magnetic topological Dirac fermions.*
Scanning tunneling microscopy has been shown to be a powerful experimental probe to detect electronic excitations and further allows us to deduce fingerprints of bosonic collective modes in superconductors. Here, we demonstrate that the inclusion of inelastic tunnel events is crucial for the interpretation of tunneling spectra of unconventional superconductors and allows us to directly probe electronic and bosonic excitations via scanning tunneling microscopy. We apply the formalism to the iron based superconductor LiFeAs.
View Article and Find Full Text PDFInelastic tunneling spectroscopy of Pb islands on Cu(111) obtained by scanning tunneling microscopy below 1 K provides a direct access to the local Eliashberg function of the islands with high energy resolution. The Eliashberg function describes the electron-phonon interaction causing conventional superconductivity. The measured Eliashberg function strongly depends on the local thickness of the Pb nanostructures and shows a sharp maximum when quantum well states of the Pb islands come close to the Fermi energy.
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