高能物理与核物理
高能物理與覈物理
고능물리여핵물리
HIGH ENERGY PHYSICS AND NUCLEAR PHYSICS
2004年
12期
1317-1323
,共7页
吴锡真%田俊龙%王宁%赵凯%李祝霞
吳錫真%田俊龍%王寧%趙凱%李祝霞
오석진%전준룡%왕저%조개%리축하
重离子融合过程%微观输运模型%动力学位垒
重離子融閤過程%微觀輸運模型%動力學位壘
중리자융합과정%미관수운모형%동역학위루
heavy ion fusion process%microscopic transport model%dynamical fusion barrier
在简要评述重核融合过程中几种主要理论模型的基础上,提出了微观输运动力学模型,即改进的量子分子动力学模型.在这个模型的框架内,我们研究了重核融合位垒的动力学行为.我们发现,随入射能量的减少,可以得到最低的动力学位垒,它趋近于绝热静态位垒.而随入射能量的增加,动力学位垒增加,最后趋近于非绝热静态位垒,这给出了位垒分布的两个边缘.在微观输运动力学模型基础上,我们还研究了在融合路径上,动力学位垒与融合体系微观构型的关系.考虑到融合过程不同时刻的单粒子位势与双中心壳模型位势的相似性,我们可以很好的研究融合过程中,在构型空间里单粒子态及相关量的时间演化行为.
在簡要評述重覈融閤過程中幾種主要理論模型的基礎上,提齣瞭微觀輸運動力學模型,即改進的量子分子動力學模型.在這箇模型的框架內,我們研究瞭重覈融閤位壘的動力學行為.我們髮現,隨入射能量的減少,可以得到最低的動力學位壘,它趨近于絕熱靜態位壘.而隨入射能量的增加,動力學位壘增加,最後趨近于非絕熱靜態位壘,這給齣瞭位壘分佈的兩箇邊緣.在微觀輸運動力學模型基礎上,我們還研究瞭在融閤路徑上,動力學位壘與融閤體繫微觀構型的關繫.攷慮到融閤過程不同時刻的單粒子位勢與雙中心殼模型位勢的相似性,我們可以很好的研究融閤過程中,在構型空間裏單粒子態及相關量的時間縯化行為.
재간요평술중핵융합과정중궤충주요이론모형적기출상,제출료미관수운동역학모형,즉개진적양자분자동역학모형.재저개모형적광가내,아문연구료중핵융합위루적동역학행위.아문발현,수입사능량적감소,가이득도최저적동역학위루,타추근우절열정태위루.이수입사능량적증가,동역학위루증가,최후추근우비절열정태위루,저급출료위루분포적량개변연.재미관수운동역학모형기출상,아문환연구료재융합로경상,동역학위루여융합체계미관구형적관계.고필도융합과정불동시각적단입자위세여쌍중심각모형위세적상사성,아문가이흔호적연구융합과정중,재구형공간리단입자태급상관량적시간연화행위.
In this paper we briefly review the fusion process of very heavy nuclear systems and some theoretical models. We propose a microscopic transport dynamic model, i.e. the Improved Quantum Molecular Dynamic model, for describing fusion reactions of heavy systems, in which the dynamical behavior of the fusion barrier in heavy fusion systems has been studied firstly. We find that with the incident energy decreasing the lowest dynamic barrier is obtained which approaches to the adiabatic static barrier and with increase of the incident energy the dynamic barrier goes up to the diabatic static barrier. We also indicate that how the dynamical fusion barrier is correlated with the development of the configuration of fusion partners along the fusion path. Associating the single-particle potentials obtained at different stages of fusion with the Two Center Shell Model, we can study the time evolution of the single particle states of fusion system in configuration space of single particle orbits along the fusion path.
