Magnetic levitation of the fusion target by coating a thin MgB_(2)superconducting shell on its outer surface has recently been proposed in inertial confinement fusion(ICF)to realize a noncontact support of the target ...Magnetic levitation of the fusion target by coating a thin MgB_(2)superconducting shell on its outer surface has recently been proposed in inertial confinement fusion(ICF)to realize a noncontact support of the target at~20 K to boost the implosion performance and fusion yield.To avoid possible effects on target ablation,the coated MgB_(2)shell is anticipated to be as thin as possible while fulfilling the target levitation requirements.Under this circumstance,the fabrication of an MgB_(2)shell with reduced thickness has been explored using a hybrid physical-chemical vapour deposition method.By gradually decreasing the deposition time,a set of MgB_(2)shells were grown on 1 mm diameter Si_(3)N_(4)spheres with the thickness reducing from 720 nm to 200 nm.The spherical shells all have a polycrystalline structure characterized by closely packed hexagonal grains,with both the grain size and thickness diminishing as the shell thickness decreases.The superconducting transition temperature Tcof the shells,as determined by both resistance and magnetization measurements,is in the range of 38-40 K and all shells exhibit ideal diamagnetism at low temperatures.For the thinnest shell of 200 nm,the superconducting critical current density Jcat 20 K reaches 8.0×10^(6)A/cm^(2)and 2.1×10^(5)A/cm^(2)under zero and 2 T applied field,respectively.The results indicate that it is experimentally feasible to fabricate MgB_(2)spherical shells with a thickness as low as 200 nm while maintaining the high Tcand Jc,thereby taking a further step towards the application of the shell in superconducting magnetic levitation for ICF.展开更多
Half-integer microwave induced steps(Shapiro steps)have been observed in many different Josephson junction systems,which have attracted a lot of attention because they signify the deviation of current phase relation(C...Half-integer microwave induced steps(Shapiro steps)have been observed in many different Josephson junction systems,which have attracted a lot of attention because they signify the deviation of current phase relation(CPR)and uncover many unconventional physical properties.In this article,we first report the discovery of half-integer Shapiro steps in MgB_(2)focused He ion beam(He-FIB)Josephson junctions.The half-integer steps'dependence on microwave frequency,temperature,microwave power,and magnetic field is also analyzed.We find that the existence of half-integer steps can be controlled by the magnetic field periodically,which is similar to that of high temperature superconductor(HTS)grain boundary junctions,and the similarity of the microstructures between gain boundary junctions and He-FIB junctions is discussed.As a consequence,we mainly attribute the physical origin of half-integer steps in MgB_(2)He-FIB junctions to the model that a He-FIB junction is analogous to a parallel junctions'array.Our results show that He-FIB technology is a promising platform for researching CPR in junctions made of different superconductors.展开更多
文摘Magnetic levitation of the fusion target by coating a thin MgB_(2)superconducting shell on its outer surface has recently been proposed in inertial confinement fusion(ICF)to realize a noncontact support of the target at~20 K to boost the implosion performance and fusion yield.To avoid possible effects on target ablation,the coated MgB_(2)shell is anticipated to be as thin as possible while fulfilling the target levitation requirements.Under this circumstance,the fabrication of an MgB_(2)shell with reduced thickness has been explored using a hybrid physical-chemical vapour deposition method.By gradually decreasing the deposition time,a set of MgB_(2)shells were grown on 1 mm diameter Si_(3)N_(4)spheres with the thickness reducing from 720 nm to 200 nm.The spherical shells all have a polycrystalline structure characterized by closely packed hexagonal grains,with both the grain size and thickness diminishing as the shell thickness decreases.The superconducting transition temperature Tcof the shells,as determined by both resistance and magnetization measurements,is in the range of 38-40 K and all shells exhibit ideal diamagnetism at low temperatures.For the thinnest shell of 200 nm,the superconducting critical current density Jcat 20 K reaches 8.0×10^(6)A/cm^(2)and 2.1×10^(5)A/cm^(2)under zero and 2 T applied field,respectively.The results indicate that it is experimentally feasible to fabricate MgB_(2)spherical shells with a thickness as low as 200 nm while maintaining the high Tcand Jc,thereby taking a further step towards the application of the shell in superconducting magnetic levitation for ICF.
基金supported by the National Natural Science Foundation of China (Grant No.12104016)the National Key Research and Development Program of China (Grant No.2020YFF01014706)。
文摘Half-integer microwave induced steps(Shapiro steps)have been observed in many different Josephson junction systems,which have attracted a lot of attention because they signify the deviation of current phase relation(CPR)and uncover many unconventional physical properties.In this article,we first report the discovery of half-integer Shapiro steps in MgB_(2)focused He ion beam(He-FIB)Josephson junctions.The half-integer steps'dependence on microwave frequency,temperature,microwave power,and magnetic field is also analyzed.We find that the existence of half-integer steps can be controlled by the magnetic field periodically,which is similar to that of high temperature superconductor(HTS)grain boundary junctions,and the similarity of the microstructures between gain boundary junctions and He-FIB junctions is discussed.As a consequence,we mainly attribute the physical origin of half-integer steps in MgB_(2)He-FIB junctions to the model that a He-FIB junction is analogous to a parallel junctions'array.Our results show that He-FIB technology is a promising platform for researching CPR in junctions made of different superconductors.
