Your search keyword '"Christopher Trainer"' showing total 6 results

1. Tomographic mapping of the hidden dimension in quasi-particle interference

Author

Igor Marković, Christopher Trainer, Akhil Rajan, Peter Wahl, Mohammad Saeed Bahramy, Timothy D. Raub, C. A. Marques, Federico Mazzola, Matthew D. Watson, Phil D. C. King, EPSRC, Scottish Funding Council, European Research Council, The Leverhulme Trust, The Royal Society, University of St Andrews. School of Physics and Astronomy, University of St Andrews. Centre for Designer Quantum Materials, University of St Andrews. Condensed Matter Physics, University of St Andrews. St Andrews Centre for Exoplanet Science, and University of St Andrews. School of Earth & Environmental Sciences

Subjects

Electronic properties and materials, TK, Science, General Physics and Astronomy, FOS: Physical sciences, Imaging techniques, Electron, Electronic structure, 01 natural sciences, Signal, Article, General Biochemistry, Genetics and Molecular Biology, TK Electrical engineering. Electronics Nuclear engineering, Settore FIS/03 - Fisica della Materia, 010305 fluids & plasmas, Surfaces, interfaces and thin films, Interference (communication), Condensed Matter::Superconductivity, 0103 physical sciences, 010306 general physics, Anisotropy, QC, Physics, Condensed Matter - Materials Science, Multidisciplinary, Plane (geometry), Scattering, Settore FIS/01 - Fisica Sperimentale, Materials Science (cond-mat.mtrl-sci), DAS, General Chemistry, Computational physics, QC Physics, Quasiparticle

Abstract

Quasiparticle interference (QPI) imaging is well established to study the low-energy electronic structure in strongly correlated electron materials with unrivalled energy resolution. Yet, being a surface-sensitive technique, the interpretation of QPI only works well for anisotropic materials, where the dispersion in the direction perpendicular to the surface can be neglected and the quasiparticle interference is dominated by a quasi-2D electronic structure. Here, we explore QPI imaging of galena, a material with an electronic structure that does not exhibit pronounced anisotropy. We find that the quasiparticle interference signal is dominated by scattering vectors which are parallel to the surface plane however originate from bias-dependent cuts of the 3D electronic structure. We develop a formalism for the theoretical description of the QPI signal and demonstrate how this quasiparticle tomography can be used to obtain information about the 3D electronic structure and orbital character of the bands., Quasiparticle interference is a powerful tool for characterization of electronic structure which leverages scattering off defects; however, it is limited to quasi two-dimensional materials. Here, the authors demonstrate a method for reconstructing electronic structure of three-dimensional materials from quasiparticle interference data.

Published

2021

2. Strain-stabilized (π,π) order at the surface of Fe1+xTe

Author

Oxana V. Magdysyuk, Vladimir Tsurkan, Craig Topping, Christopher Trainer, Andreas W. Rost, Christoph Heil, Soumendra Nath Panja, Alois Loidl, Chi Ming Yim, Peter Wahl, Alexandra S. Gibbs, EPSRC, University of St Andrews. Centre for Designer Quantum Materials, University of St Andrews. School of Physics and Astronomy, University of St Andrews. School of Chemistry, and University of St Andrews. Condensed Matter Physics

Subjects

Materials science, Bioengineering, 02 engineering and technology, law.invention, chemistry.chemical_compound, law, Telluride, Low-temparature scanning tunneling microscopy, Antiferromagnetism, ddc:530, General Materials Science, Uniaxial strain, QC, Superconductivity, Condensed matter physics, Iron telluride, Mechanical Engineering, Doping, DAS, General Chemistry, Charge order, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Magnetic field, QC Physics, chemistry, Scanning tunneling microscope, 0210 nano-technology, Ground state, Monoclinic crystal system

Abstract

C.M.Y., S.N.P., A.W.R., and P.W. acknowledge support from EPSRC through EP/S005005/1, and C.To. and A.W.R. through EP/P024564/1. C.M.Y. acknowledges additional support from a Shanghai talent program and funding through the Shanghai Pujiang Program (20PJ1408200). C.H. acknowledges support from the Austrian Science Fund (FWF), project no. P 32144-N36, and the VSC4 of the Vienna University of Technology. A key property of many quantum materials is that their ground state depends sensitively on small changes of an external tuning parameter, e.g., doping, magnetic field, or pressure, creating opportunities for potential technological applications. Here, we explore tuning of the ground state of the nonsuperconducting parent compound, Fe1+xTe, of the iron chalcogenides by uniaxial strain. Iron telluride exhibits a peculiar (π, 0) antiferromagnetic order unlike the (π, π) order observed in the Fe-pnictide superconductors. The (π, 0) order is accompanied by a significant monoclinic distortion. We explore tuning of the ground state by uniaxial strain combined with low-temperature scanning tunneling microscopy. We demonstrate that, indeed under strain, the surface of Fe1.1Te undergoes a transition to a (π, π)-charge-ordered state. Comparison with transport experiments on uniaxially strained samples shows that this is a surface phase, demonstrating the opportunities afforded by 2D correlated phases stabilized near surfaces and interfaces. Publisher PDF

Published

2021

3. Magnetic surface reconstruction in the van der Waals antiferromagnet Fe1+xTe

Author

Christoph Heil, Efrain E. Rodriguez, Mark Green, Vladimir Tsurkan, Chris Stock, Alois Loidl, Christopher Trainer, Chi Ming Yim, M. Songvilay, A. Stunault, Peter Wahl, N. Qureshi, EPSRC, University of St Andrews. School of Physics and Astronomy, University of St Andrews. Centre for Designer Quantum Materials, and University of St Andrews. Condensed Matter Physics

Subjects

Materials science, cond-mat.supr-con, Magnetism, TK, NDAS, FOS: Physical sciences, 02 engineering and technology, 01 natural sciences, law.invention, TK Electrical engineering. Electronics Nuclear engineering, Superconductivity (cond-mat.supr-con), symbols.namesake, Condensed Matter - Strongly Correlated Electrons, law, 0103 physical sciences, Antiferromagnetism, Neutron, 010306 general physics, QC, Superconductivity, Condensed Matter - Materials Science, Condensed matter physics, Strongly Correlated Electrons (cond-mat.str-el), Condensed Matter - Superconductivity, Materials Science (cond-mat.mtrl-sci), 021001 nanoscience & nanotechnology, Symmetry (physics), cond-mat.mtrl-sci, QC Physics, symbols, Scanning tunneling microscope, van der Waals force, cond-mat.str-el, 0210 nano-technology, Surface reconstruction

Abstract

Fe$_{1+x}$Te is a two dimensional van der Waals antiferromagnet that becomes superconducting on anion substitution on the Te site. The parent phase of Fe$_{1+x}$Te is sensitive to the amount of interstitial iron situated between the iron-tellurium layers displaying collinear magnetic order coexisting with low temperature metallic resistivity for small concentrations of interstitial iron $x$ and helical magnetic order for large values of $x$. While this phase diagram has been established through scattering [see for example E. E. Rodriguez $\textit{et al.}$ Phys. Rev. B ${\bf{84}}$, 064403 (2011) and S. R\"ossler $\textit{et al.}$ Phys. Rev. B ${\bf{84}}$, 174506 (2011)], recent scanning tunnelling microscopy measurements [C. Trainer $\textit{et al.}$ Sci. Adv. ${\bf{5}}$, eaav3478 (2019)] have observed a different magnetic structure for small interstitial iron concentrations $x$ with a significant canting of the magnetic moments along the crystallographic $c$ axis of $\theta$=28 $\pm$ 3$^{\circ}$. In this paper, we revisit the magnetic structure of Fe$_{1.09}$Te using spherical neutron polarimetry and scanning tunnelling microscopy to search for this canting in the bulk phase and compare surface and bulk magnetism. The results show that the bulk magnetic structure of Fe$_{1.09}$Te is consistent with collinear in-plane order ($\theta=0$ with an error of $\sim$ 5$^{\circ}$). Comparison with scanning tunnelling microscopy on a series of Fe$_{1+x}$Te samples reveals that the surface exhibits a magnetic surface reconstruction with a canting angle of the spins of $\theta=29.8^{\circ}$. We suggest that this is a consequence of structural relaxation of the surface layer resulting in an out-of-plane magnetocrystalline anisotropy. The magnetism in Fe$_{1+x}$Te displays different properties at the surface when the symmetry constraints of the bulk are removed., Comment: 11 pages, 6 figures, to be Published in Phys. Rev. B

Published

2021

4. Probing magnetic exchange interactions with helium

Author

Chi Ming Yim, Vladimir Tsurkan, Christopher Trainer, Peter Wahl, Liam Farrar, Alois Loidl, Christoph Heil, EPSRC, University of St Andrews. School of Physics and Astronomy, University of St Andrews. Centre for Designer Quantum Materials, and University of St Andrews. Condensed Matter Physics

Subjects

Nuclear physics, Physics, QC Physics, Condensed Matter::Superconductivity, TK, General Physics and Astronomy, DAS, ddc:530, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, QC, TK Electrical engineering. Electronics Nuclear engineering, Magnetic exchange

Abstract

Funding: CT and PW acknowledge support from EPSRC (EP/R031924/1) and CMY and LSF from EP/S005005/1. C.H. acknowledges support by the Austrian Science Fund (FWF) Project No. P32144-N36 and the VSC-4 of the Vienna University of Technology. The work was partially supported by the Deutsche Forschungsgemeinschaft (DFG) through Transregional Research Collaboration TRR 80 (Augsburg, Munich, and Stuttgart). Controlling and sensing spin-polarization of electrons forms the basis of spintronics. Here, we report a study of the effect of helium on the spin-polarization of the tunneling current and magnetic contrast in spin-polarized Scanning Tunneling Microscopy. We show that the magnetic contrast in SP-STM images recorded in the presence of helium depends sensitively on the tunneling conditions. From tunneling spectra and their variation across the atomic lattice we establish that the helium can be reversibly ejected from the tunneling junction by the tunneling electrons. The energy of the tunneling electrons required to eject the helium depends on the relative spin-polarization of the tip and sample, making the microscope sensitive to the magnetic exchange interactions. We show that the time-averaged spin polarization of the tunneling current is suppressed in the presence of helium and thereby demonstrate voltage control of the spin polarization of the tunneling current across the tip-sample junction. Postprint

Published

2021

5. Observation of Dirac surface states in the noncentrosymmetric superconductor BiPd

Author

Giorgio Levy, Ana Maldonado, Andreas P. Schnyder, Darren C. Peets, Alexander Yaresko, Andrea Damascelli, Ulrich Starke, Chi Ming Yim, Christopher Trainer, E. Rampi, Andreas Stohr, Peter Wahl, Christian R. Ast, Hadj M. Benia, Klaus Kern, EPSRC, University of St Andrews. School of Physics and Astronomy, and University of St Andrews. Condensed Matter Physics

Subjects

Dirac (software), FOS: Physical sciences, 02 engineering and technology, Electronic structure, 01 natural sciences, law.invention, law, Quantum mechanics, 0103 physical sciences, 010306 general physics, Electronic band structure, QC, Surface states, Spin-½, Physics, Condensed Matter - Materials Science, Condensed matter physics, Spintronics, Materials Science (cond-mat.mtrl-sci), DAS, 021001 nanoscience & nanotechnology, T Technology, QC Physics, Scanning tunneling microscope, 0210 nano-technology, Bloch wave

Abstract

Materials with strong spin-orbit coupling (SOC) have in recent years become a subject of intense research due to their potential applications in spintronics and quantum information technology. In particular, in systems which break inversion symmetry, SOC facilitates the Rashba-Dresselhaus effect, leading to a lifting of spin degeneracy in the bulk and intricate spin textures of the Bloch wave functions. Here, by combining angular resolved photoemission (ARPES) and low temperature scanning tunneling microscopy (STM) measurements with relativistic first-principles band structure calculations, we examine the role of SOC in single crystals of noncentrosymmetric BiPd. We report the detection of several Dirac surface states, one of which exhibits an extremely large spin splitting. Unlike the surface states in inversion-symmetric systems, the Dirac surface states of BiPd have completely different properties at opposite faces of the crystal and are not trivially linked by symmetry. The spin-splitting of the surface states exhibits a strong anisotropy by itself, which can be linked to the low in-plane symmetry of the surface termination., Comment: 6 page letter, + supplementary material

Published

2016

6. Cryogenic STM in 3D vector magnetic fields realized through a rotatable insert

Author

Chi Ming Yim, Christopher Trainer, Martin McLaren, Peter Wahl, EPSRC, University of St Andrews. School of Physics and Astronomy, and University of St Andrews. Condensed Matter Physics

Subjects

Materials science, Magnetism, TK, 02 engineering and technology, 01 natural sciences, TK Electrical engineering. Electronics Nuclear engineering, law.invention, Magnetization, law, 0103 physical sciences, 010306 general physics, Instrumentation, QC, Vector magnetic fields, Condensed matter physics, DAS, Spin polarized scanning tunneling microscopy, Conductive atomic force microscopy, 021001 nanoscience & nanotechnology, Magnetic field, QC Physics, Magnet, Magnetic force microscope, Scanning tunneling microscope, 0210 nano-technology, Spin-polarized scanning tunneling microscopy

Abstract

We acknowledge funding from EPSRC (EP/L505079/1 and EP/I031014/1). Spin-polarized scanning tunneling microscopy (SP-STM) performed in vector magnetic fields promises atomic scale imaging of magnetic structure, providing complete information on the local spin texture of a sample in three dimensions. Here, we have designed and constructed a turntable system for a low temperature STM which in combination with a 2D vector magnet provides magnetic fields of up to 5 T in any direction relative to the tip-sample geometry. This enables STM imaging and spectroscopy to be performed at the same atomic-scale location and field-of-view on the sample, and most importantly, without experiencing any change on the tip apex before and after field switching. Combined with a ferromagnetic tip, this enables us to study the magnetization of complex magnetic orders in all three spatial directions. Postprint

Published

2017