超流体

Superfluid helium is used in many scientific applications due to its unique properties.
超流氦因其独特的性质被用于许多科学研究中。
The behavior of superfluids is still not fully understood by physicists.
物理学家尚未完全理解超流体的行为。
The phenomenon of superfluidity was first observed in liquid helium at extremely low temperatures.
超流现象最早是在极低温度下的液态氦中观察到的。
The flow of a superfluid through a narrow channel can exhibit quantum mechanical effects.
超流体在狭窄通道中的流动可以表现出量子力学效应。
Superfluids have zero viscosity, which allows them to flow without resistance.
超流体具有零粘度，这使得它们可以无阻力地流动。
The study of superfluids has led to the development of new technologies, such as superconducting magnets.
对超流体的研究已经导致了新技术的发展，如超导磁铁。
The behavior of superfluids under extreme conditions, such as high pressure or strong magnetic fields, is an area of active research.
在极端条件下，如高压或强磁场下超流体的行为是活跃研究的领域。
The interaction between a superfluid and a solid surface can lead to interesting phenomena, like the formation of quantized vortices.
超流体与固体表面之间的相互作用可能导致有趣的现像，如量子涡旋的形成。
The discovery of superfluidity in other materials besides helium has opened up new avenues for research.
除了氦之外，在其他材料中发现超流性为研究开辟了新的途径。
The study of superfluids has implications for our understanding of fundamental physics, including the behavior of matter at the quantum scale.
对超流体的研究对我们理解基础物理学有影响，包括物质在量子尺度上的行为。