62 research outputs found
Ultrafast switching to a stable hidden topologically protected quantum state in an electronic crystal
Hidden states of matter with novel and unusual properties may be created if a
system out of equilibrium can be induced to follow a trajectory to a state
which is inaccessible or does not even exist under normal equilibrium
conditions. Here we report on the discovery of a hidden (H) topologically
protected electronic state in a layered dichalcogenide 1T-TaS2 crystal reached
as a result of a quench caused by a single 35 fs laser pulse. The properties of
the H state are markedly different from any other state of the system: it
exhibits a large drop of electrical resistance, strongly modified single
particle and collective mode spectra and a marked change of optical
reflectivity. Particularly important and unusual, the H state is stable for an
arbitrarily long time until a laser pulse, electrical current or thermal erase
procedure is applied, causing it to revert to the thermodynamic ground state.
Major observed events can be reproduced by a kinetic model describing the
conversion of photo excited electrons and holes into an electronically ordered
crystal, thus converting a Mott insulator to a conducting H state. Its
long-time stability follows from the topological protection of the number of
periods in the electronic crystal.Comment: 21 pages and 5 figures, separate supplementary materia
Controlled vaporization of the superconducting condensate in cuprate superconductors sheds light on the pairing boson
We use ultrashort intense laser pulses to study superconducting state
vaporization dynamics in La(2-x)Sr(x)CuO4 (x=0.1 and 0.15) on the femtosecond
timescale. We find that the energy density required to vaporize the
superconducting state is 2+- 0.8 K/Cu and 2.6 +- 1 K/Cu for x=0.1 and 0.15
respectively. This is significantly greater than the condensation energy
density, indicating that the quasiparticles share a large amount of energy with
the boson glue bath on this timescale. Considering in detail both spin and
lattice energy relaxation pathways which take place on the relevant timescale
of picoseconds, we rule out purely spin-mediated pair-breaking in favor of
phonon-mediated mechanisms, effectively ruling out spin-mediated pairing in
cuprates as a consequence.Comment: 5 pages of article plus 4 pages of supplementary materia
Quasiparticle relaxation dynamics in spin-density-wave and superconducting SmFeAsO_{1-x}F_{x} single crystals
We investigate the quasiparticle relaxation and low-energy electronic
structure in undoped SmFeAsO and near-optimally doped SmFeAsO_{0.8}F_{0.2}
single crystals - exhibiting spin-density wave (SDW) ordering and
superconductivity respectively - using pump-probe femtosecond spectroscopy. In
the undoped single crystals a single relaxation process is observed, showing a
remarkable critical slowing down of the QP relaxation dynamics at the SDW
transition temperature T_{SDW}\simeq125{K}. In the superconducting (SC)
crystals multiple relaxation processes are present, with distinct SC state
quasiparticle recombination dynamics exhibiting a BCS-like T-dependent
superconducting gap, and a pseudogap (PG)-like feature with an onset above 180K
indicating the existence of a pseudogap of magnitude
2\Delta_{\mathrm{PG}}\simeq120 meV above T_{\mathrm{c}}. From the pump-photon
energy dependence we conclude that the SC state and PG relaxation channels are
independent, implying the presence of two separate electronic subsystems. We
discuss the data in terms of spatial inhomogeneity and multi-band scenarios,
finding that the latter is more consistent with the present data.Comment: Replaced by the correct versio
Nonlinear order parameter oscillations and lattice coupling in strongly-driven charge-density-wave systems
The anharmonic response of charge-density wave (CDW) order to strong
laser-pulse perturbations in 1T-TaS_2 and TbTe_3 is investigated by means of a
multiple-pump-pulse time-resolved femtosecond optical spectroscopy. We observe
remarkable anharmonic effects hitherto undetected in the systems exhibiting
collective charge ordering. The efficiency for additional excitation of the
amplitude mode by a laser pulse becomes periodically modulated after the mode
is strongly excited into a coherently oscillating state. A similar effect is
observed also for some other phonons, where the cross-modulation at the
amplitude-mode frequency indicates anharmonic interaction of those phonons with
the amplitude mode. By analyzing the observed phenomena in the framework of
time-dependent Ginzburg-Landau theory we attribute the effects to the
anharmonicity of the mode potentials inherent to the broken symmetry state of
the CDW systems
Tracking Cooper Pairs in a Cuprate Superconductor by Ultrafast Angle-Resolved Photoemission
In high-temperature superconductivity, the process that leads to the
formation of Cooper pairs, the fundamental charge carriers in any
superconductor, remains mysterious. We use a femtosecond laser pump pulse to
perturb superconducting Bi2Sr2CaCu2O8+{\delta}, and study subsequent dynamics
using time- and angle-resolved photoemission and infrared reflectivity probes.
Gap and quasiparticle population dynamics reveal marked dependencies on both
excitation density and crystal momentum. Close to the d-wave nodes, the
superconducting gap is sensitive to the pump intensity and Cooper pairs
recombine slowly. Far from the nodes pumping affects the gap only weakly and
recombination processes are faster. These results demonstrate a new window into
the dynamical processes that govern quasiparticle recombination and gap
formation in cuprates.Comment: 22 pages, 9 figure
Relaxation Dynamics of Photoinduced Changes in the Superfluid Weight of High-Tc Superconductors
In the transient state of d-wave superconductors, we investigate the temporal
variation of photoinduced changes in the superfluid weight. We derive the
formula that relates the nonlinear response function to the nonequilibrium
distribution function. The latter qunatity is obtained by solving the kinetic
equation with the electron-electron and the electron-phonon interaction
included. By numerical calculations, a nonexponential decay is found at low
temperatures in contrast to the usual exponential decay at high temperatures.
The nonexponential decay originates from the nonmonotonous temporal variation
of the nonequilibrium distribution function at low energies. The main physical
process that causes this behavior is not the recombination of quasiparticles as
previous phenomenological studies suggested, but the absorption of phonons.Comment: 18 pages, 12 figures; to be published in J. Phys. Soc. Jpn. Vol. 80,
No.
Diamagnetism of real-space pairs above Tc in hole doped cuprates
The nonlinear normal state diamagnetism reported by Lu Li et al. [Phys. Rev.
B 81, 054510 (2010)] is shown to be incompatible with an acclaimed Cooper
pairing and vortex liquid above the resistive critical temperature. Instead it
is perfectly compatible with the normal state Landau diamagnetism of real-space
composed bosons, which describes the nonlinear magnetization curves in less
anisotropic cuprates La-Sr-Cu-O (LSCO) and Y-Ba-Cu-O (YBCO) as well as in
strongly anisotropic bismuth-based cuprates in the whole range of available
magnetic fields.Comment: 4 pages, 4 figure
Electron-Phonon Coupling in High-Temperature Cuprate Superconductors Determined from Electron Relaxation Rates
We determined electronic relaxation times via pump-probe optical spectroscopy
using sub-15 fs pulses for the normal state of two different cuprate
superconductors.We show that the primary relaxation process is the
electron-phonon interaction and extract a measure of its strength, the second
moment of the Eliashberg function\lambda=800\pm200 meV^{2} for
La_{1.85}Sr_{0.15}CuO_{4} and \lambda=400\pm100 meV^{2} for
YBa_{2}Cu_{3}O_{6.5}. These values suggest a possible fundamental role of the
electron-phonon interaction in the superconducting pairing mechanism.Comment: As published in PR
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