Nonlinear rovibrational polarization response of water vapor to ultrashort long-wave infrared pulses

Schuh, K.; Rosenow, Phil; Kolesík, M.; Wright, E. M.; Koch, S. W.; Moloney, Jerome V.

doi:10.1103/physreva.96.043818

Cited by 6 publications

(5 citation statements)

References 21 publications

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“…Due to the rapidly increasing amount of high-quality data placed into molecular spectroscopy databases, it is worth mentioning here that laser-induced dynamics can also be simulated for molecules for which spectroscopic databases, containing rovibrational energy levels as well as transition amplitudes between the corresponding eigenstates, are available. This interesting approach was pursued, for example, in Owens et al (2017) and Schuh et al (2017). reported the extension of the time-independent nuclear-motion code GE-NIUSH with time-dependent quantum-dynamical features and results are presented there for the coherent inhibition and enhancement of tunneling in NH 3 isotopomers.…”

Section: Stationary-state Computations Serving Dynamical Studiesmentioning

confidence: 99%

Exact Numerical Methods for Stationary-State-Based Quantum Dynamics of Complex Polyatomic Molecules

Császár

Fábri

Szidarovszky

2021

Molecular Spectroscopy and Quantum Dynamics

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The fourth age of quantum chemistry oers fully flexible, black-box-type protocols for the accurate and detailed study of nuclear motions, applicable equally well to semirigid, floppy, flexible, polytopic, fluxional, and quasistructural polyatomic molecular systems, including complexes and clusters. Several codes, based on advanced fourth-age protocols, have been developed for the variational (or variational-like) solution of the timeindependent nuclear-motion (rotational-vibrational) Schrödinger equation. These codes yield accurate rovibrational energy levels, wavefunctions, and to some extent quantumnumber assignments for bound, resonance, and scattering states, revealing important spectroscopic and dynamical characteristics about the systems studied. When no approximations are introduced to the kinetic energy part of the rovibrational Hamiltonian, the accuracy of the computed results, assuming the validity of the Born-Oppenheimer approximation, depends solely on the accuracy of the representation of the potential energy surface utilized during these computations. From the point of view of potential applications it is important to emphasize that the most general codes can be employed both in full and any number of reduced dimensions. Several a posteriori analysis tools are available to improve the understanding of the extreme amount of numerical results produced by the stationary-state nuclear-motion computations. As shown through a few examples, these stationary-state solutions can straightforwardly be utilized for detailed quantum-dynamics studies. The applications briefly detailed at the end of this chapter help appreciate the power of the fourth-age quantum-chemical techniques developed and available to the spectroscopic and dynamics communities.

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Section: Stationary-state Computations Serving Dynamical Studiesmentioning

confidence: 99%

Exact Numerical Methods for Stationary-State-Based Quantum Dynamics of Complex Polyatomic Molecules

Császár

Fábri

Szidarovszky

2021

Molecular Spectroscopy and Quantum Dynamics

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“…In that case, one has to solve thousands of ordinary differential equations for each point in space instead of just a few in our case, so the time required for simulations would grow up accordingly from total of several months to many years. The (t, r+z) propagation simulations with inclusion of nonlinear rovibrational response are possible only if one truncates this system to the system consisting fewer ordinary differential equations [32]. However, the validity of this truncation [32] is limited to the intensity of ∼10TW cm −2 .…”

Section: Simulations Of the Divergent Electromagnetic Radiation In Vamentioning

confidence: 99%

“…The (t, r+z) propagation simulations with inclusion of nonlinear rovibrational response are possible only if one truncates this system to the system consisting fewer ordinary differential equations [32]. However, the validity of this truncation [32] is limited to the intensity of ∼10TW cm −2 . In our experiment and simulations the intensity up to ∼1000TW cm −2 is attained, therefore the truncation suggested in [32] cannot be applied straightforwardly in our experimental conditions.…”

Section: Simulations Of the Divergent Electromagnetic Radiation In Vamentioning

confidence: 99%

“…However, the validity of this truncation [32] is limited to the intensity of ∼10TW cm −2 . In our experiment and simulations the intensity up to ∼1000TW cm −2 is attained, therefore the truncation suggested in [32] cannot be applied straightforwardly in our experimental conditions. Indeed, the calculation of vacuum intensity in the geometry of our experiment yields I v ≈2 PW cm −2 .…”

Section: Simulations Of the Divergent Electromagnetic Radiation In Vamentioning

confidence: 99%

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THz generation from laser-induced breakdown in pressurized molecular gases: on the way to terahertz remote sensing of the atmospheres of Mars and Venus

et al. 2020

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The present paper studies the generation of terahertz (THz) radiation in CO 2 in comparison with atmospheric air at a wide range of pressures. We established experimentally and explained theoretically that for these gases there are optimal pressures at about 1bar for air and 0.5bar for CO 2 under which the efficiency of conversion from near-infrared to THz frequencies is the highest. We consider the possibility of applying femtosecond laser-induced THz generation for the study of the atmosphere of Mars and found that the overall THz yield near the surface of Mars is just a factor of 6 lower than on Earth. Comparable THz energy on the two planets is associated with underdense plasma on Earth (∼10% of neutrals) and full double ionization of carbon dioxide on Mars (∼200% of neutrals), the latter opening great perspective for THz remote sensing of trace gases in the Martian atmosphere.

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“…Beyond the linear contribution from rovibrational response, nonlinear contributions are to be expected for high enough intensities. In order to include these into simulations, we applied the optical Bloch equations to transition data from the HITRAN database 21 . Since the amount of data in HITRAN is rather prohibitive, a selection procedure based on transition strength and detuning from the carrier frequency was applied, reducing the number of transitions from more than 140,000 to 12,709.…”

Section: Nonlinear Hitranmentioning

confidence: 99%

Simulation of LWIR TW ultrashort pulses over kilometer ranges in the atmosphere

Παναγιωτόπουλος

Rosenow

Schuh

et al. 2018

Ultrafast Bandgap Photonics III

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We have identified major paradigm shifts relative to near-IR filamentation when high power multiple terawatt laser pulses are propagated at mid-IR and long-IR wavelengths within key atmospheric transmission windows. Individual filaments at near-IR (800 nm) wavelengths typically persist only over tens of centimeters, despite the whole beam supporting them being sustained over about a Rayleigh range. In the important mid-IR atmospheric window (3.2 -4 µm) optical carrier wave self-steepening (carrier shocks) tend to dominate and modify the onset of long range filaments. These shocks generate bursts of higher harmonic dispersive waves that constrain the intensity growth of the filament to well below the traditional ionization limit, making long range low loss propagation possible. For long wavelength pulses in the 8-12 µm atmospheric transmission window, many-electron dephasing collisions from separate gas species act to dynamically suppress the traditional Kerr self-focusing lens and leads to a new type of whole beam self-trapping over multiple Rayleigh ranges. This prediction is key, since strong linear diffraction at these wavelengths are the major limitation and normally requires large launch beam apertures. We will present simulation results that predict multiple Rayleigh range propagation paths for whole beam self-trapping and will also discuss some recent efforts to extend the HITRAN linear atmospheric transmission/refractive index database to include nonlinear responses of important atmospheric molecular constituents.

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Nonlinear rovibrational polarization response of water vapor to ultrashort long-wave infrared pulses

Cited by 6 publications

References 21 publications

Exact Numerical Methods for Stationary-State-Based Quantum Dynamics of Complex Polyatomic Molecules

Exact Numerical Methods for Stationary-State-Based Quantum Dynamics of Complex Polyatomic Molecules

THz generation from laser-induced breakdown in pressurized molecular gases: on the way to terahertz remote sensing of the atmospheres of Mars and Venus

Simulation of LWIR TW ultrashort pulses over kilometer ranges in the atmosphere

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