自1954年费米去世后,还没有哪一位物理学家同时是一名精通的实验主义者和一名最主要的理论家。
Since Fermi's death in 1954, no physicist has been at once a master experimentalist and a leading theoretician.
该理论不仅可应用于重电子金属的合金系统,还适合于讨论最新发现的重费米子绝缘体中的掺杂效应。
Our theory can be applied not only to the alloy systems of heavy electron metals, but also to the discussion of doping effects in newly discovered heavy - fermion insulators.
本文采用理想费米体系统计力学有关理论和拉普拉斯变换,严格推导了朗道抗磁性的有关计算公式。
In this paper I have strictly derived these formulae about Landau Diamagnetism by using the theory of statistical mechanics of ideal Fermi system and Laplace transformation.
以简并费米气体模型在天体物理中的应用为例,说明了量子统计理论在现代物理研究领域有着十分重要的作用。
The application of degeneration Fermi gas model in astrophysics proves that quantum statistical theory plays a vitally important role in study area of modern physics.
对于一维电子系统来说费米液体理论也不是一个好的模型,因为当应用多体微扰讨论时有红外发散,使这种最常用的方法失效了。
But it's not a much appropriate model on one-dimensional systems because of infrared divergences when many-body pertebation theory is used, thus this normal solution failed.
在费米弱作用理论乃至弱电统一理论中,都是把中微子当作无静止质量的粒子来处理的。
In the Fermi weak interaction theory and even in the electro-weak unification theory, the neutrino is looked as the massless particle.
本文根据费米气体模型理论,研究金属中自由电子气的能量,讨论电子的最高能量、平均能量和电子气的能级密度。
This paper, based on the Fermi gas model, studies the energy of free electron gas in metal, discusses the highest energy, the average energy and the energy level density of free electrongas.
费米的成绩,在理论和实验物理,这是一种独特的壮举在这样一个时代中的科学事业,都趋向于专门化的一个方面或其他。
Fermi's accomplishments were in both theoretical and experimental physics, a unique feat in an age in which scientific endeavors have tended to specialize on one aspect or the other.
理论预言了四代通常费米子和四代异常费米子。
This theory predicts four generations of ordinary fermions and four generations of peculiar fermions.
通过理论分析,利用理想二极管外加磁场的方法,证明了真空中热电子发射的电子动能分布符合费米-狄拉克分布。
When an ideal diode was alive under a magnetic field, it could emit a thermal electron from its negative plate.
通过理论分析,利用理想二极管外加磁场的方法,证明了真空中热电子发射的电子动能分布符合费米-狄拉克分布。
When an ideal diode was alive under a magnetic field, it could emit a thermal electron from its negative plate.
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