English

Radiation-tolerant polarized solid target

Instrumentation and Detectors 2025-08-12 v1 Nuclear Experiment

Abstract

Polarized targets evolved into indispensable tools in particle and nuclear physics. However, the polarized solid target is degraded by high-intense beam irradiation, known as radiation damage due to target heating and radical generation. We demonstrated a radiation-tolerant polarized solid target operating at room temperature. An annealing allows the spontaneous repair of the damage by reducing unwanted radicals. Using a single crystal of p\it p-terphenyl doped with 0.01 mol\% pentacene-d\it d14_{14}, Dynamic Nuclear Polarization using photoexcited triplet electrons (Triplet-DNP) was applied to proton spins at room temperature and in 0.39 T. For the proof of concept, a deuteron beam with an energy of 135 MeV/u and the intensities of 107^7-109^9 counts per second (cps) was irradiated. The proton polarization was determined to be 3.0\% ±\pm0.2\%(stat.)\rm{{(stat.)}} ±\pm0.1\%(sys.)\rm {{(sys.)}} from a scattering asymmetry. The polarization was almost not attenuated up to 109^9 cps, but the target crystal was yellowed. The visible-light absorption spectroscopy suggested irreversible radiation damage due to missing protons by the knock-out reaction. The room-temperature polarized solid target allows impractical experiments with the conventional target system, leading to a next-generation spin-dependent accelerator science.

Keywords

Cite

@article{arxiv.2508.06549,
  title  = {Radiation-tolerant polarized solid target},
  author = {K. Tateishi and Y. Saito and D. Takahashi and K. Sekiguchi and K. Aradono and K. Hirasawa and Y. Maeda and Y. Nagao and H. Nishibata and S. Otsuka and H. Sakai and H. Sugahara and K. Suzuki and T. Uesaka and T. Wakasa and A. Watanabe},
  journal= {arXiv preprint arXiv:2508.06549},
  year   = {2025}
}

Comments

4 pages, 3 figures

R2 v1 2026-07-01T04:41:35.977Z