An Ultrahigh Energy-Range Thomson Parabola Spectrometer to Investigate Laser-Driven Proton-Ion Acceleration

Benjamin Lawrence-Sanderson; Hernan Quevedo; Andrew Yandow; Ganesh Tiwari; Griffin D. Glenn; C. Grant Richmond; Michael Donovan; Todd Ditmire

An Ultrahigh Energy-Range Thomson Parabola Spectrometer to Investigate Laser-Driven Proton-Ion Acceleration

POSTER

Abstract

Here, we report the development of a Thomson Parabola Spectrometer capable of simultaneously resolving protons and low-Z ions across an energy range of 1-200 MeV. This new design utilizes a dual image plate and dual electrode-magnet pairs to achieve a 200 MeV energy range and a maximum relative error of $\Delta$E/E $<$ 2$\%$. The first image plate collects the low energy protons and ions, but is offset from the neutral beam line to allow the higher energy particle to move on to a second electrode-magnet pair and image plate. This scheme decreases the size of the spectrometer's laboratory footprint. This new Thomson Parabola Spectrometer will be used to detect and resolve ion energy spectras generated from Texas Petawatt laser-driven ion acceleration experiments at high and ultra-high intensity regimes.

^*This work is supported by the U.S. Department of Energy, Office of Science, Office of Fusion Energy Sciences, under Award Number DE-SC0019167.

Authors

Benjamin Lawrence-Sanderson
- University of Texas at Austin
Hernan Quevedo
- University of Texas at Austin
Andrew Yandow
- University of Texas at Austin
Ganesh Tiwari
- UT Austin
- Argonne National Laboratory (current), University of Texas at Austin (former)
Griffin D. Glenn
- SLAC National Accelerator Laboratory
- Stanford University (current), University of Texas at Austin (former)
C. Grant Richmond
- University of Texas at Austin
Michael Donovan
- University of Texas at Austin
Todd Ditmire
- UT Austin
- Center for High Energy Density Science, University of Texas at Austin
- University of Texas at Austin