2021
DOI: 10.21203/rs.3.rs-871300/v1
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Three-dimensional synchronous proton radiography for dynamic magnetic fields in laser-produced high-energy-density plasmas

Abstract: Understanding the generation and evolution of magnetic fields in high-energy-density plasmas is a major scientific challenge in broad research areas including astrophysics, cosmology, and laser fusion energy. However, the fully three-dimensional (3D) topologies of such dynamic magnetic fields are still unknown yet. Here we report experiments of the first 3D synchronous proton radiography for self-generated magnetic fields in respectively laser-produced low-Z CH and high-Z Cu plasmas. The radiography images sho… Show more

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Cited by 2 publications
(1 citation statement)
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“…Similar radiography images of laser-ablated Cu plasmas are also obtained, by which we estimate that its expansion velocity is on the same order due to the similar charge-to-mass ratio Z/A. These self-generated Biermann magnetic field topologies are also verified by our three-dimensional (3D) synchronous proton radiography experiment 30 . To extract more quantitative information from the radiographys, we use the inverse field-reconstruction code "PROBLEM" 31 to recover the path-integrated magnetic fields ψ, see Methods.…”
Section: Features Of Self-generated Biermann Magnetic Fieldssupporting
confidence: 81%
“…Similar radiography images of laser-ablated Cu plasmas are also obtained, by which we estimate that its expansion velocity is on the same order due to the similar charge-to-mass ratio Z/A. These self-generated Biermann magnetic field topologies are also verified by our three-dimensional (3D) synchronous proton radiography experiment 30 . To extract more quantitative information from the radiographys, we use the inverse field-reconstruction code "PROBLEM" 31 to recover the path-integrated magnetic fields ψ, see Methods.…”
Section: Features Of Self-generated Biermann Magnetic Fieldssupporting
confidence: 81%