如果理论正确,一些缪子中微子在旅途之中将变成电子中微子。
If theory is correct, some will have changed their spots and become electron-neutrinos during the intervening journey.
T2K实验的目的是看当它们到达超级神冈探测器的时候,是否仍然是缪子中微子。
The point is to see if they are still muon-neutrinos when they arrive at Super-Kamiokande.
自发破缺的结果除电子和电子中微子外,还出现新的中微子以及一个带电的和两个中性重轻子。
After the spontaneous symmetry breaking, we have electron and its neutrino, a new charged heavy lepton and its neutrino, two neutral heavy leptons.
它们能“振动”或改变形态,这意味着LHC产生的μ子中微子可以转变为OPERA探测器设计用来测量的τ子中微子。
They can “oscillate” or change identities, which means that the mu neutrinos produced at the LHC can turn into tau neutrinos which the OPERA detector is designed to measure.
它们能“振动”或改变形态,这意味着LHC产生的μ子中微子可以转变为OPERA探测器设计用来测量的τ子中微子。
They can "oscillate" or change identities, which means that the mu neutrinos produced at the LHC can turn into tau neutrinos which the OPERA detector is designed to measure.
然后还有中微子,W和Z波色子,类电子的μ粒子和τ粒子,还有胶子——它的作用是将夸克聚合成团。
Then there are neutrinos, W and Z bosons, the electron-like muon and tau particles, and gluons—which hold quarks together in groups.
有一个轻子是中性的,叫做中微子。
中微子也有反常,反常量是轻子亚夸克结构动态模型的必然结果。
There is anomalousness in a neutrino as well, and the anomalous quantities are the inevitable outcome of the dynamical model of the subquark structure of a lepton.
当中微子使一种夸克转化为另一种夸克时,会发射出一个轻子。
当中微子使一种夸克转化为另一种夸克时,会发射出一个轻子。
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