Abstract:Iron-based superconductors (IBSs), discovered in 2008, formed the second high-Tc superconductor family after cuprate superconductors, and over the past decade have been the subject of extensive research into their physical nature and application potential. With their attractions of very high upper critical fields and small electromagnetic anisotropy, tremendous advances have been made in wire research and development (R&D) to explore the potential of IBSs for high-field applications. In recent years, rapid pro… Show more
“…The Fe-based superconductors (FBS), the second class of high-temperature superconductors beside the cuprates, are considered as possible candidates for high-field magnet applications 1 – 5 . Among them, Ln FeAs(O,F) ( Ln : Nd and Sm) has the highest depairing current density J d of ~ 170 MA/cm 2 at zero kelvin 6 .…”
The recent realisations of hydrogen doped LnFeAsO (Ln = Nd and Sm) superconducting epitaxial thin films call for further investigation of their structural and electrical transport properties. Here, we report on the microstructure of a NdFeAs(O,H) epitaxial thin film and its temperature, field, and orientation dependencies of the resistivity and the critical current density Jc. The superconducting transition temperature Tc is comparable to NdFeAs(O,F). Transmission electron microscopy investigation supported that hydrogen is homogenously substituted for oxygen. A high self-field Jc of over 10 MA/cm2 was recorded at 5 K, which is likely to be caused by a short London penetration depth. The anisotropic Ginzburg–Landau scaling for the angle dependence of Jc yielded temperature-dependent scaling parameters γJ that decreased from 1.6 at 30 K to 1.3 at 5 K. This is opposite to the behaviour of NdFeAs(O,F). Additionally, γJ of NdFeAs(O,H) is smaller than that of NdFeAs(O,F). Our results indicate that heavily electron doping by means of hydrogen substitution for oxygen in LnFeAsO is highly beneficial for achieving high Jc with low anisotropy without compromising Tc, which is favourable for high-field magnet applications.
“…The Fe-based superconductors (FBS), the second class of high-temperature superconductors beside the cuprates, are considered as possible candidates for high-field magnet applications 1 – 5 . Among them, Ln FeAs(O,F) ( Ln : Nd and Sm) has the highest depairing current density J d of ~ 170 MA/cm 2 at zero kelvin 6 .…”
The recent realisations of hydrogen doped LnFeAsO (Ln = Nd and Sm) superconducting epitaxial thin films call for further investigation of their structural and electrical transport properties. Here, we report on the microstructure of a NdFeAs(O,H) epitaxial thin film and its temperature, field, and orientation dependencies of the resistivity and the critical current density Jc. The superconducting transition temperature Tc is comparable to NdFeAs(O,F). Transmission electron microscopy investigation supported that hydrogen is homogenously substituted for oxygen. A high self-field Jc of over 10 MA/cm2 was recorded at 5 K, which is likely to be caused by a short London penetration depth. The anisotropic Ginzburg–Landau scaling for the angle dependence of Jc yielded temperature-dependent scaling parameters γJ that decreased from 1.6 at 30 K to 1.3 at 5 K. This is opposite to the behaviour of NdFeAs(O,F). Additionally, γJ of NdFeAs(O,H) is smaller than that of NdFeAs(O,F). Our results indicate that heavily electron doping by means of hydrogen substitution for oxygen in LnFeAsO is highly beneficial for achieving high Jc with low anisotropy without compromising Tc, which is favourable for high-field magnet applications.
“…In the past years, mechanical deformation processes such as flat rolling, isostatic pressing, and uniaxial pressing have significantly improved the J c of 122-type IBS in USA, Europe, China, Japan, and Australia ( Weiss et al, 2012 ; Malagoli et al, 2015 ; Zhang et al, 2014 ; Gao et al, 2017 ; Shabbir et al, 2017 ). High transport J c above the practical level of 10 5 A/cm 2 (4.2 K, 10 T) has been achieved by hot or cold uniaxial press combined with flat rolling process for PIT wires and tapes ( Hosono et al, 2018 ; Yao and Ma, 2019 ). A synergetic microstructural tailoring for mass density, grain alignment and micro-cracks is the key to realize such high J c performance.…”
Section: Materials Challenges and Current State Of Practical Applicationsmentioning
confidence: 99%
“…Last year, a practical level critical current density up to 1.1 × 10 5 A cm −2 at 4.2 K and 10 T was achieved in Cu/Ag sheathed Ba-122 tapes by combing flat rolling to induce grain texture and a subsequent HIP densification, which is a scalable and cost-effective manufacturing route ( Liu et al, 2021 ). Figure 7 State-of-the-art critical current density J c of 122-IBS based on PIT technique showing much weaker field dependence up to 33 T compared with that of Nb-Ti and Nb 3 Sn LTS conductors Data source for IBS short samples: Ba-122 tapes ( J c at 10-13 T, 24-27 T and 25-33 T were measured in a 14 T superconducting magnet, a 28 T hybrid magnet and a 35 T water-cooled magnet, respectively) ( Yao and Ma, 2019 ; Huang et al, 2018 ); Ba-122 wires ( Pyon et al, 2020 ). Data for LTS conductors were collected from nationalmaglab.org ( Lee, 2018 ).…”
Section: Materials Challenges and Current State Of Practical Applicationsmentioning
Summary
Superconducting materials hold great potential to bring radical changes for electric power and high-field magnet technology, enabling high-efficiency electric power generation, high-capacity loss-less electric power transmission, small lightweight electrical equipment, high-speed maglev transportation, ultra-strong magnetic field generation for high-resolution magnetic resonance imaging (MRI) systems, nuclear magnetic resonance (NMR) systems, future advanced high energy particle accelerators, nuclear fusion reactors, and so on. The performance, economy, and operating parameters (temperatures and magnetic fields) of these applications strongly depend on the electromagnetic and mechanical properties, as well as the manufacturing and material cost of superconductors. This perspective examines the basic properties relevant to practical applications and key issues of wire fabrication for practical superconducting materials, and describes their challenges and current state in practical applications. Finally, future perspectives for their opportunities and development in the applications of superconducting power and magnetic technologies are considered.
“…Regarding possible applications, the 122 compounds can operate at higher magnetic fields than MgB 2 [2], are less prone to flux jumps, are robust to impurity doping [3], and the misalignment of the grains can be higher than in cuprates when producing wires or bulks. These advantages were already manifested in several efforts to produce 122-based wires/tapes (see, e.g., the recent review of Yao et al [4]), and trapped fields above 1 T were already recorded in bulk, HIP (hot isostatic pressed)-processed 122 samples [5]. On the other hand, the 122 material demonstrates several unique properties, e.g., it undergoes an isostructural transition under pressure [6,7,8,9], from which important information on the nature of superconductivity can be obtained.…”
Section: Introductionmentioning
confidence: 99%
“…This was discussed in detail in several publications [11,12,13,14]. The recent advances in jc of tapes [4] and bulk materials [5,15,16] are, therefore, due to these improved sample preparation routes.…”
The flux pinning properties of reacted-and-pressed Ba0.6K0.4Fe2As2 powder were measured using magnetic hysteresis loops in the temperature range 20 K ≤ T ≤ 35 K. The scaling analysis of the flux pinning forces ( F p = j c × B , with j c denoting the critical current density) following the Dew-Hughes model reveals a dominant flux pinning provided by normal-conducting point defects ( δ l -pinning) with only small irreversibility fields, H irr , ranging between 0.5 T (35 K) and 16 T (20 K). Kramer plots demonstrate a linear behavior above an applied field of 0.6 T. The samples were further characterized by electron backscatter diffraction (EBSD) analysis to elucidate the origin of the flux pinning. We compare our data with results of Weiss et al. (bulks) and Yao et al. (tapes), revealing that the dominant flux pinning in the samples for applications is provided mainly by grain boundary pinning, created by the densification procedures and the mechanical deformation applied.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
