878 research outputs found
How Climate, Uplift and Erosion Shaped the Alpine Topography
Decades of scientific research on the European Alps have helped quantify the vast array of processes that shape the Earth’s surface. Patterns in rock exhumation, surface erosion and topographic changes can be compared to sediment yields preserved in sedimentary basins or collected from modern rivers. Erosion-driven isostatic uplift explains up to ~50% of the modern geodetic rock uplift rates; the remaining uplift reveals the importance of internal processes (tectonics, deep-seated geodynamics) and external processes (glacial rebound, topographic changes). We highlight recent methodological and conceptual developments that have contributed to our present view of the European Alps, and we provide suggestions on how to fill the gaps in our understanding
Quasiparticle Liquid in the Highly Overdoped Bi2212
We present results from the study of a highly overdoped (OD) Bi2212 with a
K using high resolution angle-resolved photoemission spectroscopy.
The temperature dependent spectra near the () point show the presence of
the sharp peak well above . From the nodal direction, we make comparison
of the self-energy with the optimally doped and underdoped cuprates, and the
Mo(110) surface state. We show that this OD cuprate appears to have properties
that approach that of the Mo. Further analysis shows that the OD has a more
-independent lineshape at the Fermi surface than the lower-doped cuprates.
This allows for a realistic comparison of the nodal lifetime values to the
experimental resistivity measurements via Boltzmann transport formulation. All
these observations point to the validity of the quasiparticle picture for the
OD even in the normal state within a certain energy and momentum range.Comment: 4 pages, 4 figure
Gapped Surface States in a Strong-Topological-Semimetal
A three-dimensional strong-topological-insulator or -semimetal hosts
topological surface states which are often said to be gapless so long as
time-reversal symmetry is preserved. This narrative can be mistaken when
surface state degeneracies occur away from time-reversal-invariant momenta. The
mirror-invariance of the system then becomes essential in protecting the
existence of a surface Fermi surface. Here we show that such a case exists in
the strong-topological-semimetal BiSe. Angle-resolved photoemission
spectroscopy and \textit{ab initio} calculations reveal partial gapping of
surface bands on the BiSe-termination of BiSe(111), where an 85
meV gap along closes to zero toward the mirror-invariant
azimuth. The gap opening is attributed to an interband
spin-orbit interaction that mixes states of opposite spin-helicity.Comment: 5 pages, 3 figure
Quasi-Particle Spectra, Charge-Density-Wave, Superconductivity and Electron-Phonon Coupling in 2H-NbSe2
High-resolution photoemission has been used to study the electronic structure
of the charge density wave (CDW) and superconducting (SC) dichalcogenide, 2H-
NbSe2. From the extracted self-energies, important components of the
quasiparticle (QP) interactions have been identified. In contrast to previously
studied TaSe2, the CDW transition does not affect the electronic properties
significantly. The electron-phonon coupling is identified as a dominant
contribution to the QP self-energy and is shown to be very anisotropic
(k-dependent) and much stronger than in TaSe2.Comment: 4 pages, 3 figures, minor changes, to appear in PR
High-energy kink in high-temperature superconductors
In conventional metals, electron-phonon coupling, or the phonon-mediated
interaction between electrons, has long been known to be the pairing
interaction responsible for the superconductivity. The strength of this
interaction essentially determines the superconducting transition temperature
TC. One manifestation of electron-phonon coupling is a mass renormalization of
the electronic dispersion at the energy scale associated with the phonons. This
renormalization is directly observable in photoemission experiments. In
contrast, there remains little consensus on the pairing mechanism in cuprate
high temperature superconductors. The recent observation of similar
renormalization effects in cuprates has raised the hope that the mechanism of
high temperature superconductivity may finally be resolved. The focus has been
on the low energy renormalization and associated "kink" in the dispersion at
around 50 meV. However at that energy scale, there are multiple candidates
including phonon branches, structure in the spin-fluctuation spectrum, and the
superconducting gap itself, making the unique identification of the excitation
responsible for the kink difficult. Here we show that the low-energy
renormalization at ~50 meV is only a small component of the total
renormalization, the majority of which occurs at an order of magnitude higher
energy (~350 meV). This high energy kink poses a new challenge for the physics
of the cuprates. Its role in superconductivity and relation to the low-energy
kink remains to be determined.Comment: 13 pages, 4 figure
Fine Details of the Nodal Electronic Excitations in BiSrCaCuO
Very high energy resolution photoemission experiments on high quality samples
of optimally doped BiSrCaCuO show new features in the
low-energy electronic excitations. A marked change in the binding energy and
temperature dependence of the near-nodal scattering rates is observed near the
superconducting transition temperature, . The temperature slope of the
scattering rate measured at low energy shows a discontinuity at ~. In the
superconducting state, coherent excitations are found with the scattering rates
showing a cubic dependence on frequency and temperature. The superconducting
gap has a d-wave magnitude with negligible contribution from higher harmonics.
Further, the bi-layer splitting has been found to be finite at the nodal point.Comment: 5 pages, 4 figure
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