Your search keyword '"Chase Calvi"' showing total 4 results

1. Micro-scale fusion in dense relativistic nanowire array plasmas

Author

Alden Curtis, Chase Calvi, James Tinsley, Reed Hollinger, Vural Kaymak, Alexander Pukhov, Shoujun Wang, Alex Rockwood, Yong Wang, Vyacheslav N. Shlyaptsev, and Jorge J. Rocca

Subjects

Science

Abstract

Neutron beams are useful studying fundamental physics problems, fusion process and material properties. Here the authors use intense laser irradiation of deuterated nanowire array targets to create high energy density plasmas capable of efficient generation of ultrafast neutron pulses.

Published

2018

2. Enhanced electron acceleration in aligned nanowire arrays irradiated at highly relativistic intensities

Author

Yong Wang, Shoujun Wang, Chase Calvi, Reed Hollinger, Jorge J. Rocca, Alden Curtis, Vyacheslav N. Shlyaptsev, Vural Kaymak, Maria Gabriela Capeluto, Alex Rockwood, Stephen Kasdorf, A. Moreau, and Alexander Pukhov

Subjects

Materials science, HOT ELECTRONS, ELECTRON ACCELERATION, Dephasing, X-RAYS, Nanowire, Physics::Optics, Electron, 01 natural sciences, HIGH ENERGY DENSITY PLASMAS, 010305 fluids & plasmas, law.invention, purl.org/becyt/ford/1 [https], law, 0103 physical sciences, LASER-MATTER INTERACTIONS, 010306 general physics, Plasma, purl.org/becyt/ford/1.3 [https], Condensed Matter Physics, Laser, Nuclear Energy and Engineering, Femtosecond, Cathode ray, Electron temperature, Atomic physics

Abstract

We report a significant enhancement in both the energy and the flux of relativistic electrons accelerated by ultra-intense laser pulse irradiation (>1 10 21 W cm-2) of near solid density aligned CD2 nanowire arrays in comparison to those from solid CD2 foils irradiated with the same laser pulses. Ultrahigh contrast femtosecond laser pulses penetrate deep into the nanowire array creating a large interaction volume. Detailed three dimensional relativistic particle-in-cell simulations show that electrons originating anywhere along the nanowire length are first driven towards the laser to reach a lower density plasma region near the tip of the nanowires, where they are accelerated to the highest energies. Electrons that reach the lower density plasma experience direct laser acceleration up to the dephasing length, where they outrun the laser pulse. This yields an electron beam characterized by a 3 higher electron temperature and an integrated flux 22.4 larger respect to foil targets. Additionally, the generation of >1 MeV photons were observed to increase up to 4.5. Fil: Moreau, A.. State University of Colorado - Fort Collins; Estados Unidos Fil: Hollinger, R.. State University of Colorado - Fort Collins; Estados Unidos Fil: Calvi, C.. State University of Colorado - Fort Collins; Estados Unidos Fil: Wang, S.. State University of Colorado - Fort Collins; Estados Unidos Fil: Wang, Y.. State University of Colorado - Fort Collins; Estados Unidos Fil: Capeluto, Maria Gabriela. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Ciudad Universitaria. Instituto de Física de Buenos Aires. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales. Instituto de Física de Buenos Aires; Argentina Fil: Rockwood, A.. State University of Colorado - Fort Collins; Estados Unidos Fil: Curtis, A.. State University of Colorado - Fort Collins; Estados Unidos Fil: Kasdorf, S.. State University of Colorado - Fort Collins; Estados Unidos Fil: Shlyaptsev, V.N.. State University of Colorado - Fort Collins; Estados Unidos Fil: Kaymak, V.. Universitat Dusseldorf; Alemania Fil: Pukhov, A.. Universitat Dusseldorf; Alemania Fil: Rocca, J.J.. State University of Colorado - Fort Collins; Estados Unidos

Published

2020

3. Micro-scale fusion in dense relativistic nanowire array plasmas

Author

Yong Wang, Vyacheslav N. Shlyaptsev, Alden Curtis, Reed Hollinger, Vural Kaymak, Alexander Pukhov, Shoujun Wang, James Tinsley, Jorge J. Rocca, Chase Calvi, and Alex Rockwood

Subjects

Materials science, Science, Nuclear Theory, Nanowire, General Physics and Astronomy, Physics::Optics, Scintillator, 01 natural sciences, 7. Clean energy, General Biochemistry, Genetics and Molecular Biology, Article, 010305 fluids & plasmas, law.invention, Optics, law, 0103 physical sciences, Neutron detection, Nuclear fusion, Neutron, 010306 general physics, Nuclear Experiment, lcsh:Science, Multidisciplinary, Dense plasma focus, business.industry, General Chemistry, Plasma, Laser, Deuterium, 13. Climate action, Femtosecond, lcsh:Q, Atomic physics, business, Ultrashort pulse

Abstract

Nuclear fusion is regularly created in spherical plasma compressions driven by multi-kilojoule pulses from the world’s largest lasers. Here we demonstrate a dense fusion environment created by irradiating arrays of deuterated nanostructures with joule-level pulses from a compact ultrafast laser. The irradiation of ordered deuterated polyethylene nanowires arrays with femtosecond pulses of relativistic intensity creates ultra-high energy density plasmas in which deuterons (D) are accelerated up to MeV energies, efficiently driving D–D fusion reactions and ultrafast neutron bursts. We measure up to 2 × 106 fusion neutrons per joule, an increase of about 500 times with respect to flat solid targets, a record yield for joule-level lasers. Moreover, in accordance with simulation predictions, we observe a rapid increase in neutron yield with laser pulse energy. The results will impact nuclear science and high energy density research and can lead to bright ultrafast quasi-monoenergetic neutron point sources for imaging and materials studies., Neutron beams are useful studying fundamental physics problems, fusion process and material properties. Here the authors use intense laser irradiation of deuterated nanowire array targets to create high energy density plasmas capable of efficient generation of ultrafast neutron pulses.

Published

2018

4. 085 PW laser operation at 33 Hz and high-contrast ultrahigh-intensity λ = 400 nm second-harmonic beamline

Author

Bradley M. Luther, Carmen S. Menoni, Chase Calvi, Yong Wang, Shoujun Wang, Jorge J. Rocca, Reed Hollinger, Alden Curtis, and Alex Rockwood

Subjects

Materials science, business.industry, Far-infrared laser, Ti:sapphire laser, Laser, 01 natural sciences, Atomic and Molecular Physics, and Optics, law.invention, 010309 optics, X-ray laser, Optics, Beamline, law, 0103 physical sciences, Femtosecond, Sapphire, Optoelectronics, Laser power scaling, 010306 general physics, business

Abstract

We demonstrate the generation of 0.85 PW, 30 fs laser pulses at a repetition rate of 3.3 Hz with a record average power of 85 W from a Ti:sapphire laser. The system is pumped by high-energy Nd:glass slab amplifiers frequency doubled in LiB3O5 (LBO). Ultrahigh-contrast λ=400 nm femtosecond pulses were generated in KH2PO4 (KDP) with >40% efficiency. An intensity of 6.5×1021 W/cm2 was obtained by frequency doubling 80% of the available Ti:sapphire energy and focusing the doubled light with an f/2 parabola. This laser will enable highly relativistic plasma experiments to be conducted at high repetition rate.

Published

2017