39 research outputs found
Large optical field enhancement for nanotips with large opening angles
We theoretically investigate the dependence of the enhancement of optical
near-fields at nanometric tips on the shape, size, and material of the tip. We
confirm a strong dependence of the field enhancement factor on the radius of
curvature. In addition, we find a surprisingly strong increase of field
enhancement with increasing opening angle of the nanotips. For gold and
tungsten nanotips in the experimentally relevant parameter range (radius of
curvature nm at nm laser wavelength), we obtain field
enhancement factors of up to for Au and for W for large
opening angles. We confirm this strong dependence on the opening angle for many
other materials featuring a wide variety in their dielectric response. For
dielectrics, the opening angle dependence is traced back to the electrostatic
force of the induced surface charge at the tip shank. For metals, the plasmonic
response strongly increases the field enhancement and shifts the maximum field
enhancement to smaller opening angles.Comment: 16 pages, 12 figure
Determination of Compton profiles at solid surfaces from first-principles calculations
Projected momentum distributions of electrons, i.e. Compton profiles above
the topmost atomic layer have recently become experimentally accessible by
kinetic electron emission in grazing-incidence scattering of atoms at
atomically flat single crystal metal surfaces. Sub-threshold emission by slow
projectiles was shown to be sensitive to high-momentum components of the local
Compton profile near the surface. We present a method to extract momentum
distribution, Compton profiles, and Wigner and Husimi phase space distributions
from ab-initio density-functional calculations of electronic structure. An
application for such distributions to scattering experiments is discussed.Comment: 13 pages, 5 figures, submitted to PR
Controlling ultrafast currents by the non-linear photogalvanic effect
We theoretically investigate the effect of broken inversion symmetry on the
generation and control of ultrafast currents in a transparent dielectric (SiO2)
by strong femto-second optical laser pulses. Ab-initio simulations based on
time-dependent density functional theory predict ultrafast DC currents that can
be viewed as a non-linear photogalvanic effect. Most surprisingly, the
direction of the current undergoes a sudden reversal above a critical threshold
value of laser intensity I_c ~ 3.8*10^13 W/cm2. We trace this switching to the
transition from non-linear polarization currents to the tunneling excitation
regime. We demonstrate control of the ultrafast currents by the time delay
between two laser pulses. We find the ultrafast current control by the
non-linear photogalvanic effect to be remarkably robust and insensitive to
laser-pulse shape and carrier-envelope phase
Ab-initio multi-scale simulation of high-harmonic generation in solids
High-harmonic generation by a highly non-linear interaction of infrared laser
fields with matter allows for the generation of attosecond pulses in the XUV
spectral regime. This process, well established for atoms, has been recently
extended to the condensed phase. Remarkably well pronounced harmonics up to
order ~30 have been observed for dielectrics. We present the first ab-initio
multi-scale simulation of solid-state high-harmonic generation. We find that
mesoscopic effects of the extended system, in particular the realistic sampling
of the entire Brillouin zone, the pulse propagation in the dense medium, and
the inhomogeneous illumination of the crystal have a strong effect on the
formation of clean harmonic spectra. Our results provide a novel explanation
for the formation of clean harmonics and have implications for a wide range of
non-linear optical processes in dense media
Electron rescattering at metal nanotips induced by ultrashort laser pulses
We report on the first investigation of plateau and cut-off structures in
photoelectron spectra from nano-scale metal tips interacting with few-cycle
near-infrared laser pulses. These hallmarks of electron rescattering,
well-known from atom-laser interaction in the strong-field regime, appear at
remarkably low laser intensities with nominal Keldysh parameters of the order
of . Quantum and quasi-classical simulations reveal that a large
field enhancement near the tip and the increased backscattering probability at
a solid-state target play a key role. Plateau electrons are by an order of
magnitude more abundant than in comparable atomic spectra, reflecting the high
density of target atoms at the surface. The position of the cut-off serves as
an in-situ probe for the locally enhanced electric field at the tip apex
Classical-quantum correspondence in atomic ionization by midinfrared pulses: Multiple peak and interference structures
Atomic ionization by strong and ultrashort laser pulses with frequencies in the midinfrared spectral region have revealed novel features such as the low-energy structures. We have performed fully three-dimensional quantum dynamical as well as classical trajectory Monte Carlo simulations for pulses with wavelengths from λ=2000 to 6000 nm. Furthermore, we apply distorted-wave quantum approximations. This allows to explore the quantum-classical correspondence as well as the (non) perturbative character of the ionization dynamics driven by long-wavelength pulses. We observe surprisingly rich structures in the differential energy and angular momentum distribution which sensitively depend on λ, the pulse duration Ïp, and the carrier-envelope phase ÏCEP