Simulations of Laser Field Emission from Nanostructures with Image Charge Trapping and Band Structure Transitions

Wang, Benjamin; Arias, Tomas; Karkare, Siddharth; Lawler, Gerard; Mann, Joshua; Nangoi, Johannes Kevin; Rosenzweig, James

doi:10.18429/JACoW-IPAC2022-MOPOMS036

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BiBTeX citation export for MOPOMS036: Simulations of Laser Field Emission from Nanostructures with Image Charge Trapping and Band Structure Transitions

@inproceedings{wang:ipac2022-mopoms036,
  author       = {B. Wang and T. Arias and S.S. Karkare and G.E. Lawler and J.I. Mann and J.K. Nangoi and J.B. Rosenzweig},
% author       = {B. Wang and T. Arias and S.S. Karkare and G.E. Lawler and J.I. Mann and J.K. Nangoi and others},
% author       = {B. Wang and others},
  title        = {{Simulations of Laser Field Emission from Nanostructures with Image Charge Trapping and Band Structure Transitions}},
  booktitle    = {Proc. IPAC'22},
% booktitle    = {Proc. 13th International Particle Accelerator Conference (IPAC'22)},
  pages        = {717--720},
  eid          = {MOPOMS036},
  language     = {english},
  keywords     = {electron, laser, simulation, vacuum, photon},
  venue        = {Bangkok, Thailand},
  series       = {International Particle Accelerator Conference},
  number       = {13},
  publisher    = {JACoW Publishing, Geneva, Switzerland},
  month        = {07},
  year         = {2022},
  issn         = {2673-5490},
  isbn         = {978-3-95450-227-1},
  doi          = {10.18429/JACoW-IPAC2022-MOPOMS036},
  url          = {https://jacow.org/ipac2022/papers/mopoms036.pdf},
  abstract     = {{Laser-induced field emission from nanostructures as a means to create high brightness electron beams has been a continually growing topic of study. Experiments using nanoblade emitters have achieved peak fields upwards of 40 GV/m, begging further investigation in this extreme regime. A recent paper has provided analytical reductions of the common semi-infinite Jellium system for pulsed incident lasers. We utilize these results as well as similar previous results to further understand the physics underlying electron rescattering-type emissions. We progress in numerically evaluating the analytical solution to attempt to more efficiently generate spectra for this system. Additionally, we use the full 1-D time-dependent Schrödinger equation with a Hartree potential and a dispersion-relation transition from material to vacuum to study the same system. We determine what importance the inclusion of the material band structure may have on emissions using this computationally challenging approach.}},
}