三元氢化物(Th,Y)H10的合成及超导电性OA
Synthesis and Superconductivity of the Ternary Hydrides(Th,Y)H10
近年来,氢基超导体在高压下实现的近室温超导引起了广泛关注,然而,大多数具有高超导转变温度(Tc)的氢化物需要在极高的压力下才能稳定,极大地限制了其应用潜力.为此,提出了在三元Th-Y-H体系中探索中等压力下获得高Tc超导体的可能性.利用金刚石对顶砧,结合原位激光加热技术,以钍(Th)、氢化钇(YH3)和氨硼烷(NH3BH3)为前驱体,在高温高压条件下合成了Th-Y-H三元氢化物.结合同步辐射X射线衍射测量与理论研究结果,确定其主要产物为立方相的(Th,Y)H10,其中Y的占比为 10%~15%.电输运测量结果显示,相近压力下其Tc较ThH10 提升约10%,在144 GPa下样品的Tc最高可达184 K,且在降压至100 GPa时仍可达 170 K,接近该压力下已知氢化物的最高Tc纪录.外加磁场下的测试进一步证实了超导的存在,并基于WHH模型和GL模型估算其上临界场分别为 52 和 39 T.研究结果表明,Th-Y-H是具有优异超导性的三元超导材料体系,通过在二元体系中合理引入新的元素,可有效调控晶体稳定性和电子性质,为在中等压力甚至低压下探索高Tc超导氢化物提供了新的思路与实验依据.
Recent achieved superconductivity near room temperature,especially in hydrogen-based super-conductors under high pressure,have attracted broad interest.However,most systems with high superconducting critical temperature(Tc)are only stable under extremely high pressures,which limits their practical applicability.This study proposes the possibility of obtaining high-Tc superconductors at moderate pressures within the ternary Th-Y-H system.The synthesis was carried out using Th,YH3,and NH3BH3 as precursors under high pressure and high temperature,applied by diamond anvil cells combined with in-situ laser heating technology.Combining with the synchrotron X-ray diffraction(XRD)measurements and theoretical studies,the main product was identified as Fm3m(Th,Y)H10,with Y accounting for approximately 10%-15%.Electrical transport measurements reveal that its Tc increases by approximately 10%,compared to ThH10 under similar pressure.At 144 GPa,the sample has a maximum Tc of 184 K,which remains at 170 K when decompressed to 100 GPa—approaching the highest level known for hydrides at this pressure.Measurements under an applied magnetic field further verify the superconductivity,with upper critical fields estimated at 52 and 39 T based on the WHH and GL models,respectively.These results indicate that the ternary Th-Y-H superconducting system is an outstanding candidate for high-Tc superconductors,and the crystal stability and electronic properties can be effectively controlled by reasonably introducing new element into the binary system.This work provides new insights and experimental evidences for exploring high-Tc superconducting hydrides under moderate or even low pressures.
宋晓旭;郝晓宽;牛景雨;高国英;田永君
燕山大学亚稳材料全国重点实验室,河北 秦皇岛 066000||燕山大学材料科学与工程学院,河北 秦皇岛 066000燕山大学亚稳材料全国重点实验室,河北 秦皇岛 066000||燕山大学材料科学与工程学院,河北 秦皇岛 066000燕山大学亚稳材料全国重点实验室,河北 秦皇岛 066000||燕山大学材料科学与工程学院,河北 秦皇岛 066000燕山大学亚稳材料全国重点实验室,河北 秦皇岛 066000||燕山大学材料科学与工程学院,河北 秦皇岛 066000燕山大学亚稳材料全国重点实验室,河北 秦皇岛 066000||燕山大学材料科学与工程学院,河北 秦皇岛 066000
数理科学
三元氢化物超导电性Th-Y-H体系高压超导转变温度
ternary hydridessuperconductivityTh-Y-H systemhigh pressuresuperconducting critical temperature
《高压物理学报》 2026 (4)
35-42,8
国家自然科学基金(52372261,52288102)河北省自然科学基金(E2024203045)河北省科技计划项目(225A1102D)国家重点研发计划(2022YFA1402300)
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