那也是我们系统的简并度。
所以你可以把它作为事实上,的系统状态的简并度,存在于某一特定温度下。
So you can think of this as the degeneracy of the system states that are actually going to exist at a particular temperature.
这里简并度是三。
也就是一个分子在格点中可能的位置数,这就是简并度。
And the number of choices of putting that one molecule is anywhere on the lattice. That's your degeneracy.
这样,对孤立系统,能量的简并度是,粒子位置可能的状态数。
So, if the system is isolated, then the degeneracy of your energy is just a number of waysthat you can flip the positions around.
于是等于简并度,乘以构型的能量。
So you can write this as the degeneracy of the configuration, times the energy of the configuration.
简并度是指具有相同能量的不同状态的数目,记为gi,这里简并度是一。
How many states, different states are there with the same energy. And that's called gi. And here it's one.
在均匀磁场中,计算两种规范下,磁场被限制在一个柱体的区域的简并度,说明了薛定谔方程的求解方法。
In even magnetic field, the degeneracy of two gauges is calculated when magnetic field is confined in a cylindrical domain. The solution method of Schrdinger equation is introduced.
并指出激光的基本特点是高光子简并度。激光的特性是由受激辐射的本质决定的。
It is shown that the basic of a laser lies in its high photon degeneracy and are governed by the nature of stimulated emission.
推导出了三维各向同性谐振子在均匀磁场中的能级表达式并讨论了其最低能级及其简并度的变化。
The formula of energy levels of two dimensional harmonic oscillator in the uniform magnetic field is derived.
推导出了三维各向同性谐振子在均匀磁场中的能级表达式并讨论了其最低能级及其简并度的变化。
The formula of energy levels of two dimensional harmonic oscillator in the uniform magnetic field is derived.
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