Massively-Parallel Computations for Nuclear Dynamics Based on a Next-Generation Theory with Multiple Slater Determinants

2022 Fiscal Year Final Research Report

• Project/Area Number: 19K14704
• Research Category: Grant-in-Aid for Early-Career Scientists
• Allocation Type: Multi-year Fund
• Review Section: Basic Section 15010:Theoretical studies related to particle-, nuclear-, cosmic ray and astro-physics
• Research Institution: Tokyo Institute of Technology (2021-2022); Niigata University (2019-2020)
• Principal Investigator: Sekizawa Kazuyuki 東京工業大学, 理学院, 准教授 (00820854)
• Project Period (FY): 2019-04-01 – 2023-03-31
• Keywords: 原子核反応 / 時間依存密度汎関数法 / 時間依存平均場理論 / 多核子移行反応 / 深部非弾性散乱 / エネルギー散逸 / 量子揺らぎ / HPC

Outline of Final Research Achievements

In this project, the so-called stochastic mean-field (SMF) theory has been employed to introduce initial quantal fluctuations in the description. The SMF theory has been successfully implemented to our parallel computational code and has been applied. As a result, it has been demonstrated that the SMF theory significantly improve the quantitative description of production cross sections for multinucleon transfer processes. Moreover, the SMF theory has been extended to describe kinetic energy distribution which otherwise could not be described before. The agreement is not yet perfect, and to figure out the origin of discrepancy is one of the future works. It has been expected that the description can be further improved by introducing correlations (mixing) of Slater determinants.

Free Research Field

原子核理論

Academic Significance and Societal Importance of the Research Achievements

本研究課題の実施期間には，時間依存密度汎関数法（Time-Dependent Density Functional Theory: TDDFT）に初期揺らぎを導入する枠組みの開発と応用を進めた．この方法は，原子核の反応だけでなく，励起・応答・核分裂等にも応用することが可能である．また，相互作用やスケールが異なるだけで，物性分野等で扱う他の量子多体系への応用も期待できる．また，この方法によって低エネルギー原子核反応に伴う物理量を微視的かつ定量的に記述できるようになったことで，未知の不安定核の生成や新奇なダイナミクスの予言等への更なる応用が期待でき，原子核物理学分野において高い学術的な意義を持つ．