目前研究量子引力最常用的方法是超弦理论,研究人员希望它能描述宇宙在最基本层面上的活动。
Today the most popular approach to quantum gravity is string theory, which researchers hope could describe happenings in the universe at the most fundamental level.
这种时空的颗粒性源于超弦理论与环圈量子重力学的最重要差异。
This granularity emerges from what is the most important difference between the two theories.
全息时空被用于某种研究量子化引力的方法,这种方法与超弦理论联系紧密。
"Holographic space-time is used in certain approaches to quantising gravity that have a strong connection to string theory, " says Cramer.
这个超弦理论的对头叫做“环圈量子重力学”,于1986年由宾西法尼亚州立大学的Abhaya shtekar提出。
Loop quantum gravity, as this rival is known, was dreamed up in 1986 by Abhay Ashtekar, of Pennsylvania State University.
在超弦理论可以解释通过假定亚原子粒子的共振或其实只是一个微小的弦振动的亚原子物理学的神秘量子法则。
The superstring theory can explain the mysterious quantum laws of sub-atomic physics by postulating that sub-atomic particles are really just resonances or vibrations of a tiny string.
但超弦理论在实验基础方面的不足,又使我们不能不立足于量子描述。
However, superstring theory is not sufficient in experiments so that we have to base on quantum description.
非对易空间中的量子力学(NCQM)最近引起了超弦理论领域物理学家们的兴趣。
Recently physicists working on superstring theory paid much attention to the quantum mechanics on non-commutative Spaces (NCQM).
非对易空间中的量子力学(NCQM)最近引起了超弦理论领域物理学家们的兴趣。
Recently physicists working on superstring theory paid much attention to the quantum mechanics on non-commutative Spaces (NCQM).
应用推荐