Unprecedented TeVm−1 acceleration gradients are modeled to be realizable using a nonlinear surface crunch-in mode in nanostructured tubes. This mode is realizable using advances in nanofabrication and solid energy density attosecond bunch compression. Three dimensional computational and analytical modeling demonstrates GeV energy gain in sub-millimeter long tubes with effective wall densities nt∼1022−24cm−3 and hundreds of nanometer core radius when driven by submicron near solid electron beams, nb∼0.05nt. Besides the many TVm−1 average gradients, strong self-focusing and nanomodulation of the beam which increases its peak density and the wakefield strength also opens up controlled high-energy photon production.
@article{arxiv.2004.09452,
title = {Nanostructured Tube Wakefield Accelerator},
author = {Aakash A. Sahai and Toshiki Tajima and Vladimir D. Shiltsev},
journal= {arXiv preprint arXiv:2004.09452},
year = {2020}
}
Comments
6 pages, 4 figures. Submitted for peer-review in March 2020 (patent filed). The mechanism in this manuscript is founded on the crunch-in nonlinear surface mode in fiber-like tube structures in continuity with the work published by the lead author in Proc. IPAC 2015 (WEPJE001) (ref.13), PRAB 20, 081004, 2017 (ref.12) and IJMPA 34, 1943009, 2019 (ref.3)