74 research outputs found
Rate equations for nitrogen molecules in ultrashort and intense x-ray pulses
We study theoretically the quantum dynamics of nitrogen molecules (N2) exposed to intense and ultrafast x-rays at a wavelength of 1.1 nm (1100eV photon energy) from the Linac Coherent Light Source (LCLS) free electron laser. Molecular rate equations are derived to describe the intertwined photoionization, decay, and dissociation processes occurring for N2. This model complements our earlier phenomenological approaches, the single-atom, symmetric-sharing, and fragmentation-matrix models of 2012 (J. Chem. Phys. 136 214310). Our rate-equations are used to obtain the effective pulse energy at the sample and the time scale for the dissociation of the metastable dication . This leads to a very good agreement between the theoretically and experimentally determined ion yields and, consequently, the average charge states. The effective pulse energy is found to decrease with shortening pulse duration. This variation together with a change in the molecular fragmentation pattern and frustrated absorption - an effect that reduces absorption of x-rays due to (double) core hole formation - are the causes for the drop of the average charge state with shortening LCLS pulse duration discovered previously
Ultrafast absorption of intense x rays by nitrogen molecules
We devise a theoretical description for the response of nitrogen molecules
(N2) to ultrashort and intense x rays from the free electron laser (FEL) Linac
Coherent Light Source (LCLS). We set out from a rate-equation description for
the x-ray absorption by a nitrogen atom. The equations are formulated using all
one-x-ray-photon absorption cross sections and the Auger and radiative decay
widths of multiply-ionized nitrogen atoms. Cross sections are obtained with a
one-electron theory and decay widths are determined from ab initio computations
using the Dirac-Hartree-Slater (DHS) method. We also calculate all binding and
transition energies of nitrogen atoms in all charge states with the DHS method
as the difference of two self-consistent field calculations (Delta SCF method).
To describe the interaction with N2, a detailed investigation of intense
x-ray-induced ionization and molecular fragmentation are carried out. As a
figure of merit, we calculate ion yields and the average charge state measured
in recent experiments at the LCLS. We use a series of phenomenological models
of increasing sophistication to unravel the mechanisms of the interaction of x
rays with N2: a single atom, a symmetric-sharing model, and a
fragmentation-matrix model are developed. The role of the formation and decay
of single and double core holes, the metastable states of N_2^2+, and molecular
fragmentation are explained.Comment: 16 pages, 6 figures, 2 tables, RevTeX4.1, supporting materials in the
Data Conservancy, revise
Characterization of Single-Shot Attosecond Pulses with Angular Streaking Photoelectron Spectra
Most of the traditional attosecond pulse retrieval algorithms are based on a so-called attosecond streak camera technique, in which the momentum of the electron is shifted by an amount depending on the relative time delay between the attosecond pulse and the streaking infrared pulse. Thus, temporal information of the attosecond pulse is encoded in the amount of momentum shift in the streaked photoelectron momentum spectrogram S(p, τ), where p is the momentum of the electron along the polarization direction and τ is the time delay. An iterative algorithm is then employed to reconstruct the attosecond pulse from the streaking spectrogram. This method, however, cannot be applied to attosecond pulses generated from free-electron x-ray lasers where each single shot is different and stochastic in time. However, using a circularly polarized infrared laser as the streaking field, a two (or three)-dimensional angular streaking electron spectrum can be used to retrieve attosecond pulses for each shot, as well as the time delay with respect to the circularly polarized IR field. Here we show that a retrieval algorithm previously developed for the traditional streaking spectrogram can be modified to efficiently characterize single-shot attosecond pulses. The methods have been applied to retrieve 188 single shots from recent experiments. We analyze the statistical behavior of these 188 pulses in terms of pulse duration, bandwidth, pulse peak energy, and time delay with respect to the IR field. The retrieval algorithm is efficient and can be easily used to characterize a large number of shots in future experiments for attosecond pulses at free-electron x-ray laser facilities
COLECCIÓN ANTONIO GONZÁLEZ. CRONISTA OFICIAL DE TELDE [Material gráfico]
Copia digital. Madrid : Ministerio de Educación, Cultura y Deporte. Subdirección General de Coordinación Bibliotecaria, 201
Imaging the ring opening reaction of 1,3-cyclohexadiene with MeV ultrafast electron diffraction
We resolve the structural dynamics of the ultrafast photoinduced ring opening reaction of 1,3-cyclohexadiene in space and time employing megaelectronvolt gas phase ultrafast electron diffraction. We, furthermore, observe coherent large amplitude motions of the photoproduct
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