Refined relic abundance calculations for thermal and non-thermal Dark Matter

• Project Area: What is dark matter? - Comprehensive study of the huge discovery space in dark matter
• Project/Area Number: 21H05452
• Research Category: Grant-in-Aid for Transformative Research Areas (A)
• Allocation Type: Single-year Grants
• Review Section: Transformative Research Areas, Section (II)
• Research Institution: The University of Tokyo
• Principal Investigator: Binder Tobias 東京大学, カブリ数物連携宇宙研究機構, 特任研究員 (30847009)
• Project Period (FY): 2021-09-10 – 2023-03-31
• Project Status: Declined (Fiscal Year 2022)
• Budget Amount: ¥2,340,000 (Direct Cost: ¥1,800,000、Indirect Cost: ¥540,000); Fiscal Year 2022: ¥1,170,000 (Direct Cost: ¥900,000、Indirect Cost: ¥270,000); Fiscal Year 2021: ¥1,170,000 (Direct Cost: ¥900,000、Indirect Cost: ¥270,000)
• Keywords: Dark Matter / relic abundance / bound-state formation / thermal field theory / Dark Matter abundance

Outline of Research at the Start

The prediction of the relic abundance for freeze-in scenarios beyond kinetic equilibrium, and heavy WIMPs featuring long-range forces is poorly understood. We study both scenarios by extending the public dark matter relic abundance code DRAKE.

Outline of Annual Research Achievements

The research purpose, as summarized in the proposal document "Refined relic abundance calculations for thermal and non-thermal Dark Matter" (March, 2021), was to explore theoretical uncertainties in the Dark Matter relic abundance prediction. In summary, the main research targets for the proposed topic about heavy WIMP production have been achieved in FY2021.

In particular, the research about Dark Matter bound state formation inside the early Universe plasma has been fruitful. The proposed (zero and finite temperature) next-to-leading order (NLO) computation of a non-abelian electric field correlator is completed and the results are published in a journal. Gauge invariance, collinear and infrared finiteness were proven. The main result in form of one-integral expressions can be used to study thermal corrections to singlet-adjoint pair transitions.

In a separate work, currently submitted to a journal, we studied an effective treatment of the coupled Boltzmann equations for an arbitrary number of bound states (and transitions). The result can straightforwardly be implemented into public relic density solvers such as DRAKE. As a part of the results, limiting expressions are also provided to bracket the impact of bound state transitions on the relic abundance without the need of computing any of those.

Research Progress Status

翌年度、交付申請を辞退するため、記入しない。

Strategy for Future Research Activity

翌年度、交付申請を辞退するため、記入しない。

Research Products

• [Journal Article] Non-Abelian electric field correlator at NLO for dark matter relic abundance and quarkonium transport (2022)
  • Author(s): Binder Tobias、Mukaida Kyohei、Scheihing-Hitschfeld Bruno、Yao Xiaojun
  • Journal Title: Journal of High Energy Physics Volume: 01 (2022) 137 Issue: 1 Pages: 137-137
  • DOI: 10.1007/jhep01(2022)137
  • Peer Reviewed / Open Access / Int'l Joint Research
• [Journal Article] Saha equilibrium for metastable bound states and dark matter freeze-out (2021)
  • Author(s): Tobias Binder, Anastasiia Filimonova, Kalliopi Petraki, and Graham White
  • Journal Title: Arxiv: 2112.00042 Volume: -
  • Int'l Joint Research