超导电性

The discovery of high-temperature superconductivity revolutionized the field of materials science.
高温超导体的发现彻底改变了材料科学领域。
Superconductivity allows for the transmission of electricity with zero loss, making it highly sought after for power grid applications.
超导性使得电力传输无损耗，因此在电网应用中极具吸引力。
In the realm of quantum computing, superconducting qubits are a leading technology due to their controllability and scalability.
在量子计算领域，由于其可控制性和可扩展性，超导量子比特成为领先技术。
The Meissner effect, where a superconductor expels magnetic fields, is a fundamental characteristic of superconductivity.
迈斯纳效应，即超导体排斥磁场，是超导性的基本特征。
Research into cuprate superconductors has been ongoing since the 1980s, aiming to understand and enhance their properties.
自20世纪80年代以来，对铜基超导体的研究一直在进行，旨在理解并提升其性能。
The development of superconducting magnets has enabled advancements in medical imaging such as MRI machines.
超导磁铁的发展促进了MRI等医学成像技术的进步。
Low-temperature superconductors require cryogenic conditions, limiting their practical applications.
低温超导体需要低温环境，这限制了它们的实际应用。
The search for room-temperature superconductivity remains one of the greatest challenges in condensed matter physics.
寻找室温超导体仍然是凝聚态物理领域的一大挑战。
Superconductivity in certain materials occurs at critical temperatures, above which they lose their superconducting properties.
某些材料中的超导性发生在临界温度以下，超过这个温度，它们就会失去超导特性。
Josephson junctions, based on superconductivity principles, are used in quantum electronics and precision measurements.
基于超导原理的约瑟夫森结被用于量子电子学和精密测量中。