Strongly enhanced current densities in superconducting coated conductors of YBa2Cu3O7−x + BaZrO3

MacManus‐Driscoll, Judith L.; FOLTYN, S. R.; Jia, Q. X.; WANG, H.; Serquis, A.; CIVALE, L.; Maiorov, B.; HAWLEY, M. E.; MALEY, M. P.; PETERSON, D. E.

doi:10.1142/9789814317665_0048

Cited by 41 publications

(54 citation statements)

References 18 publications

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“…Further improvement of the performance of these films can be expected when columnar-type defects are incorporated. Experiences accumulated over the past decades on creating self-assembled columnar defects in cuprates films 35 via chemical synthesis could help promote similar critical current enhancement in iron-based superconducting films. In this respect, SmFeAsO 1 À x F x -based superconducting products with performance comparable to the state-of-the-art of cuprates can be expected.…”

Section: Discussionmentioning

confidence: 99%

Huge critical current density and tailored superconducting anisotropy in SmFeAsO0.8F0.15 by low-density columnar-defect incorporation

et al. 2013

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Iron-based superconductors could be useful for electricity distribution and superconducting magnet applications because of their relatively high critical current densities and upper critical fields. SmFeAsO 0.8 F 0.15 is of particular interest as it has the highest transition temperature among these materials. Here we show that by introducing a low density of correlated nano-scale defects into this material by heavy-ion irradiation, we can increase its critical current density to up to 2 Â 10 7 A cm À 2 at 5 K-the highest ever reported for an ironbased superconductor-without reducing its critical temperature of 50 K. We also observe a notable reduction in the thermodynamic superconducting anisotropy, from 8 to 4 upon irradiation. We develop a model based on anisotropic electron scattering that predicts that the superconducting anisotropy can be tailored via correlated defects in semimetallic, fully gapped type II superconductors.

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Section: Discussionmentioning

confidence: 99%

Huge critical current density and tailored superconducting anisotropy in SmFeAsO0.8F0.15 by low-density columnar-defect incorporation

et al. 2013

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“…Superconductive/ thermoelectric material performance can be improved by adding nanoparticles (NPs) that disrupt the order parameter/phonon density while leaving the matrix and electronic structure of the superconductor/thermoelectric intact. [1][2][3][4] In the case of thermoelectrics, the reduction of lattice thermal conductivity through phonon scattering by size-controlled NPs has been predicted in the seminal paper by Hicks and Dresselhaus. 5 This approach has already been demonstrated to be effective in metallic materials, such as Bi 2 Te 3 /Sb 2 Te 3 multilayers 6 and PbTe bulk material 1 with natural NP additions with a significant enhancement of the figure of merit (ZT) that has reached up to~2 at 800 K. In comparison with metallic materials, oxides offer the advantages of reduced cost, nontoxicity and higher stability at high temperatures.…”

Section: Introductionmentioning

confidence: 99%

“…After the seminal works demonstrated that second-phase additions 4,12 to RE-Ba-Cu-O (rare earth (RE)) (REBCO) thin films grown using pulsed laser deposition (PLD) significantly improved the current carrying performance in an applied magnetic field, 3,[13][14][15] it was shown that the morphology of the inclusions depends on the synthesis 1 Materials Physics and Applications Division, Los Alamos National Laboratory, Los Alamos, NM, USA; 2 Graduate School of Science and Technology, Seikei University, Tokyo, Japan; 3 Nanostructures Research Laboratory, Japan Fine Ceramics Center, Nagoya, Japan; 4 National Institute of Advanced Industrial Science and Technology, Ibaraki, Japan; method (that is, in situ vs ex situ). 3,16 Moreover, recent work has shown that large quantities (⩾10%) of second-phase additions are required to obtain the desired level of performance in superconductors.…”

Section: Introductionmentioning

confidence: 99%

Tuning nanoparticle size for enhanced functionality in perovskite thin films deposited by metal organic deposition

et al. 2017

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Because of pressing global environmental challenges, focus has been placed on materials for efficient energy use, and this has triggered the search for nanostructural modification methods to improve performance. Achieving a high density of tunable-sized second-phase nanoparticles while ensuring the matrix remains intact is a long-sought goal. In this paper, we present an effective, scalable method to achieve this goal using metal organic deposition in a perovskite system REBa 2 Cu 3 O 7 (rare earth (RE)) that enhances the superconducting properties to surpass that of previous achievements. We present two industrially compatible routes to tune the nanoparticle size by controlling diffusion during the nanoparticle formation stage by selecting the second-phase material and modulating the precursor composition spatially. Combining these routes leads to an extremely high density (8 × 10 22 m − 3 ) of small nanoparticles (7 nm) that increase critical currents and reduce detrimental effects of thermal fluctuations at all magnetic field strengths and temperatures. This method can be directly applied to other perovskite materials where nanoparticle addition is beneficial.

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“…This approach resulted in pancake-like 211 particles with an average size of 15 nm distributed in the YBCO film, which produced some enhancement in pinning along c and much higher improvements for H//a,b. Correlated pinning along the c-axis was also observed when seemingly randomly distributed 10-nm-wide BaZrO 3 (BZO) particles were inserted in the YBCO film by ablating from a PLD target synthesized using Ba excess and added Zr [41]. In the last study the observed correlated pinning along the c-axis was related to misfit dislocations between the nanoparticles and the superconducting matrix, which aligned along the c direction, with an areal density of 400 µm -2 compared to 80 µm -2 for undoped YBCO films.…”

Section: Artificial Introduction Of Flux Pinning Nanostructuresmentioning

confidence: 99%

Nanotechnologies to Enable High‐Performance Superconductors for Energy Applications

Cantoni

Goyal

2013

Nanotechnology for the Energy Challenge

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High Temperature Superconductors (HTS) wires or coated conductors (CC) hold promise to revolutionize the transmission of electricity enabling the present electric grid to meet the world's growing energy needs. Although superconducting wires can carry 150 times more power than copper wires of the same cross section, further performance improvements are necessary for the superconducting technology to become costcompetitive. This objective can be achieved by introducing and controlling nano-sized defects and non-superconducting phases within the superconducting film's matrix. Such nanostructures, when carefully engineered, significantly increase the loss-free current sustained by the superconductor through a mechanism known as flux pinning. This chapter is a review of the various types of nanostructures that are artificially introduced in superconducting films to enhance the superconductor's performance. Different approaches, materials, and techniques are discussed and the most recent results in this field compared. The last section of this chapter discusses an additional example of 2 nanotechnology employment in superconducting wires. This nanotechnology can be regarded as an atomic surface treatment designed to enable the right crystallographic orientation of the superconducting film deposited on the metal template. Overcoming limitations to superconductors' performanceEfficient transport and storage of energy are two key factors in the formidable quest to meet the world's growing energy needs. Because electricity is the energy form of choice for most uses, and the most effective way to transport energy from and to different locations, addressing the energy problem means necessarily addressing the shortcomings of the present electric power grid. Capacity and reliability of the present grid are entirely inadequate to accommodate an expected growth in energy demand of 50% by the year 2030, most of which will be concentrated in urbanized areas whose infrastructures are already severely congested. In addition, 7 -10 % of the electricity generated is lost in the grid by heat dissipation, and transmission limitations have already caused black outs throughout the world. Superconducting cables made with high critical temperature (T c ) cuprate superconductors have the potential to transform the grid to meet the 21 st century demands. Such cables can carry five times more power then copper cables with the same cross section and exhibit considerable lower losses (loss-free dc transmission). Because lower losses enable longer transmission lengths, superconductors provide the best choice for building a new, non-fragmented, super grid that will enable massive long-distance power transmission, interconnect entire continents, and provide widespread, local energy storage. In such a grid, renewable source power plants in the most remote areas can deliver power anywhere in the continent according to real time demands, and episodic 3 surpluses are readily stored for future use. High temperature superconducting (HTS) cabl...

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Strongly enhanced current densities in superconducting coated conductors of YBa₂Cu₃O_7−x + BaZrO₃

Cited by 41 publications

References 18 publications

Huge critical current density and tailored superconducting anisotropy in SmFeAsO0.8F0.15 by low-density columnar-defect incorporation

Huge critical current density and tailored superconducting anisotropy in SmFeAsO0.8F0.15 by low-density columnar-defect incorporation

Tuning nanoparticle size for enhanced functionality in perovskite thin films deposited by metal organic deposition

Nanotechnologies to Enable High‐Performance Superconductors for Energy Applications

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