Modeling Polarization Sensitivity of Qweak Apparatus for Transverse Beam Spin

Radloff, Robert W., Jr.

January 2018

No description available.

Nuclear Physics

Physics

physics

rescattering

qweak

transverse

jefferson lab

asymmetry

Predictions from a Simple Hadron Rescattering Model for <i>pp</i> Collisions at the LHC

Truesdale, David Christopher

January 2010

No description available.

Nuclear Physics

HBT

femtoscopy

ALICE

LHC

heavy-ion

pp

rescattering

Wavelength Dependent High-Order Above Threshold Ionization Enhancements in Atoms

Talbert, Bradford Kent

January 2021

No description available.

Physics

Strong Field Physics

ATI

Rescattering Plateau

HATI

Argon Enhancement

Laser physics

Cr:ZnSe

AMO

Ultrafast imaging: laser induced electron diffraction

Xu, Junliang

January 1900

Doctor of Philosophy / Department of Physics / Chii-Dong Lin / Imaging of molecules has always occupied an essential role in physical, chemical and biological sciences. X-ray and electron diffraction methods routinely achieve sub-angstrom spatial resolutions but are limited to probing dynamical timescales longer than a picosecond. With the advent of femtosecond intense lasers, a new imaging paradigm emerges in last decade based on laser-induced electron diffraction (LIED). It has been placed on a firm foundation by the quantitative rescattering theory, which established that large-angle e-ion elastic differential cross sections (DCS) can be retrieved from the LIED spectrum. We further demonstrate that atomic potentials can be accurately retrieved from those extracted DCSs at energies from a few to several tens of electron volts. Extending to molecules, we show mid-infrared (mid-IR) lasers are crucial to generate high-energy electron wavepackets (> 100 eV) to resolve the atomic positions in a molecule. These laser-driven 100 eV electrons can incur core-penetrating collisions where the momentum transfer is comparable to those attained in conventional keV electron diffraction. Thus a simple independent atom model (IAM), which has been widely used in conventional electron diffractions, may apply for LIED. We theoretically examine and validate the applicability of IAM for electron energies above 100 eV using e-molecule large-angle collision data obtained in conventional experiments, demonstrating its resolving powers for bond lengths about 0.05 angstrom. The Validity of IAM is also checked by an experimental LIED investigation of rare gas atoms in the mid-IR regime. We show that the electron’s high energy promotes core-penetrating collisions at large scattering angles, where the e-atom interaction is dominated by the strong short range atomic-like potential. Finally, we analyze the measured LIED spectrum of N[subscript]2 and O[subscript]2 at three mid-IR wavelengths (1.7, 2.0, and 2.3 μm). As expected, the retrieved bond lengths of N[subscript]2 at three wavelengths are about same as the equilibrium N[subscript]2 bond length. For O[subscript]2, the data is also consistent with a bond length contraction of 0.1 angstrom within 4-6 fs after tunnel ionization. This investigation establishes a foundation for this novel imaging method for spatiotemporal imaging of gas-phase molecules at the atomic scale.

Ultrafast imaging

Laser induced electron diffraction

Above-threshold ionization

Strong laser physics

quantitative rescattering theory

Independent atom model

Physics (0605)