English

High-precision luminescence cryothermometry strategy by using hyperfine structure

Optics 2025-11-25 v1

Abstract

A novel, to the best of our knowledge, ultralow-temperature luminescence thermometry strategy is proposed, based on a measurement of relative intensities of hyperfine components in the spectra of Ho3+^{3+} ions doped into a crystal. A 7^{7}LiYF4_4:Ho3+^{3+} crystal is chosen as an example. First, we show that temperatures in the range 10-35 K can be measured using the Boltzmann behavior of the populations of crystal-field levels separated by an energy interval of 23 cm1^{-1}. Then we select the 6089 cm1^{-1} line of the holmium 5I55I7^5I_5 \rightarrow ^5I_7 transition, which has a well-resolved hyperfine structure and falls within the transparency window of optical fibers (telecommunication S band), to demonstrate the possibility of measuring temperatures below 3 K. The temperature TT is determined by a least-squares fit to the measured intensities of all eight hyperfine components using the dependence I(ν)=I1exp(bν)I(\nu) = I_1 \exp(-b\nu), where I1I_1 and b=aν+νkTb = a\nu + \frac{\nu}{kT} are fitting parameters and a accounts for intensity variations due to mixing of wave functions of different crystal-field levels by the hyperfine interaction. In this method, the absolute and relative thermal sensitivities grow at TT approaching zero as 1T2\frac{1}{T^2}.and 1T\frac{1}{T}, respectively. We theoretically considered the intensity distributions within hyperfine manifolds and compared the results with experimental data. Application of the method to experimentally measured relative intensities of hyperfine components of the 6089 cm1^{-1} PL line yielded T=3.7±0.2T = 3.7 \pm 0.2 K. For a temperature of 1 K, an order of magnitude better accuracy is expected.

Keywords

Cite

@article{arxiv.2511.19088,
  title  = {High-precision luminescence cryothermometry strategy by using hyperfine structure},
  author = {Marina N. Popova and Mosab Diab and Boris Z. Malkin},
  journal= {arXiv preprint arXiv:2511.19088},
  year   = {2025}
}

Comments

24 pages, 6 figures

R2 v1 2026-07-01T07:52:06.625Z