高能重离子碰撞开辟了研究多粒子体系的新领域。
The high energy heavy-ion collisions open a new field in nuclear physics.
用RBUU方法研究了中高能重离子碰撞中K-介子产额及谱的情况。
We have investigated the yield and the spectrum of the K~- mesons in the heavy-ion collisions with the relativistic RBUU approach.
简述了高能重离子碰撞中流体动力学模型的基本公式以及公式的求解方法。
The fundamental formulas of source coherence theory are derived, and the Quantum Statistics space-time descriptive method about classical current is introduced.
高能重离子碰撞物理学主要目的是研究极端条件下核物质的性质,探测夸克—胶子等离子体(QGP)。
The major goal of high energy heavy ion collision is to investigate nuclear matter properties under extreme conditions and detect quark-gluon plasma (QGP).
通过高能重离子碰撞发现夸克胶子等离子体这一新物质形态有助于我们更好地理解量子色动力学的禁闭特性。
Study of high-energy heavy-ion collisions found quark-gluon plasma of this new material forms will help us better understand confinement , a crucial feature of QCD.
介子由于其寿命小于碰撞中心区火球的寿命,可能反映高能重离子碰撞中心区的物质形态信息而被寄予厚望,受到广泛关注。
Rho meson gets quite much attention and is expected to carry information about the central fireball formed in the heavy ion collision, because its lifetime is shorter than that of the fireball.
我们将会看到在RHIC能量下的高能重离子碰撞中,存在很强的横向扩张运动,并且随着碰撞中心度的增大而变得更加激烈。
It shows that in high energetic nuclear collisions at RHIC energies, there exists very strong transverse expansion, which becomes stronger with increasing colliding centrality.
进一步,学习椭圆流在不同对撞能量下对中心度和系统大小的依赖性是研究高能重离子碰撞产生的新物质形态性质的有效途径。
Thus, the centrality and system-size dependence of elliptic flow at different beam energies can be used to study the properties of the matter created in heavy ion collisions.
进一步,学习椭圆流在不同对撞能量下对中心度和系统大小的依赖性是研究高能重离子碰撞产生的新物质形态性质的有效途径。
Thus, the centrality and system-size dependence of elliptic flow at different beam energies can be used to study the properties of the matter created in heavy ion collisions.
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