超重核

超重核~（266）Hs形成截面的入射道依赖

Entrance Channel Dependence of Production Cross Sections of Superheavy Nucleus ~ ( 266 ) Hs

超重核合成的同位素依赖探讨

On Isotope Dependence of Superheavy Nucleus Production

基于RMF理论对超重核结构和合成以及滴线外核的研究

Structure and Synthesis for Superheavy Element Based on Relativistic Mean Field Theory and Research on Nuclide beyond Drip-line

所计算的以Pb为靶的冷熔合超重核形成截面和以48Ca为弹核的热熔合超重核形成激发函数与已知的实验值在合理的范围内符合。

The formation cross sections of the super-heavy nuclei from Pb-based cold fusion and excitation functions from ~ 48Ca induced hot fusion are reasonably consistent with known experimental data .

在超重核区应用Viola-Seaborg公式研究α衰变寿命

Study on Half-lives of α Decay in Region on Super-heavy Nuclei by Viola-Seaborg Formula

对超重核基态性质的系统性研究

Systematic Study of Ground State Properties of Super Heavy Nuclei

超重核合成中的靶核形变效应

Overweight Effects of Target Deformation on Synthesis of Superheavy Nuclei

超重核α衰变寿命的理论研究

Theoretical Studies on α - decay Half-lives of Superheavy Nuclei

超重核合成截面计算中几个问题的探讨

Approach Synthesis of Superheavy Nuclei from Some Aspects of Cross Section Calculations

重离子熔合反应形成超重核的截面研究

Formation Cross Sections of Super Heavy Nuclei by Heavy Ion Fusion Reactions

热熔合反应合成超重核产生截面的同位素依赖性

Isotopic Dependence of Production Cross Sections of Superheavy Nuclei in Hot Fusion Reactions

用宏观-微观模型系统计算偶-偶超重核基态性质

Systematic Calculation on Ground State Properties of Superheavy Even-Even Nuclei with Macroscopic-Microscopic Model

超重核合成理论模型简介

Introduction of Theoretical Models for Superheavy Nuclei Formation

超重核的基态性质

Ground - state Properties of Superheavy Nuclei

超重核合成进展

Progress of synthesis of Superheavy Nuclei

对单粒子能级的计算和分析表明超重核的壳结构是形变和同位旋相关的。

The investigation of single-particle levels shows that the shell structure is deformed and isospin dependent .

超重核的壳结构

Shell Structure of Superheavy Nuclei

利用宏观-微观模型研究超重核区原子核的α衰变能和衰变寿命

α decay energies and half-lives of the nucleus in region of super-heavy nuclei from a macro-microscopic model

超重核密度的计算

Density Properties of Superheavy Nuclei

用宏观&微观模型研究超重核~（271）110及其衰变链的α衰变能和衰变寿命

Research on Decay Energies and Half-lives of Super-heavy Nuclei and the Nucleus of Its Disintegration Chain with a Macroscopic-microscopic Model

推广的液滴模型对超重核~（288）115及其α衰变链性质的研究

Properties of the Superheavy Nuclei ~ ( 288 ) 115 and Its α - Decay Chain in a Generalized Liquid-Drop Model

在双核模型框架下，用数值解主方程方法计算了超重核的熔合几率。

In the dinuclear system conception , the master equation is solved numerically to calculate the fusion probabilities of super-heavy nuclei .

简单介绍了兰州-北京-吉森合作组对合成超重核的重离子反应进行的初步研究。

In recent years , the Lanzou-Beijing-Giessen collaboration has studied the heavy ion reactions which are lead to the formation of super-heavy nuclei .

在改进的量子分子动力学模型基础上系统地研究了超重核合成中的入射道静态势和动力学势。

Based on an improved quantum molecular dynamics model the static and dynamic potential in the entrance channel of synthesis of superheavy nuclei are studied .

通过在形成超重核的重离子俘获和熔合过程中引入位垒分布函数的方法对双核模型做了进一步发展。

The dinuclear system model has been further developed by introducing the barrier distribution function method in the process of heavy-ion capture and fusion to synthesize superheavy nuclei .

计算了不同入射能量时各角动量分波对熔合概率和超重核存活概率的影响以及对蒸发剩余截面的贡献。

For different incident energies and different angular momentum , the effects on fusion and survival probability and the contribution to evaporation residue cross section have been given .

简单回顾了超重核的理论研究现状，讨论了形变对长寿命重核α衰变半衰期的影响。

Status of theoretical studies on superheavy nuclei is simply reviewed . We investigate the influence of nuclear deformation on half-lives of α - decay for long lifetime nuclei beyond ~ ( 208 ) Pb .

在重核和超重原子核中量子混沌问题的研究

Investigation on Quantum Chaos in Heavy and Superheavy Nuclei

实验证实，用重离子碰撞合成超重原子核时，准裂变对熔合的抑制是非常重要的。

The experimental measurements have provided the evidence that the suppression of fusion cross-section caused by quasi-fission is very important for the synthesis of super-heavy nuclei by heavy ion collisions .

双核系统势能面还提供重离子碰撞合成超重原子核的最佳激发能和最佳弹靶组合的信息。

The dinuclear system potential energy surface also gives the information about the optimum projectile-target combination , as well as the optimum excitation energy for the synthesis of super-heavy nuclei by heavy ion collisions .