Faculty of Science and Technology

Masashi MIURA

  (三浦 正志)

Profile Information

Affiliation
Professor, Faculty of Science and Technology , Seikei University
長期客員研究員, 米国 ロスアラモス国立研究所
Degree
博士(工学)( 名古屋大学 【短縮修了】)

J-GLOBAL ID
201401081210995658
researchmap Member ID
B000243002

External link

Awards

 27

Major Papers

 92
  • Masashi Miura, Serena Eley, Kazumasa Iida, Kota Hanzawa, Jumpei Matsumoto, Hidenori Hiramatsu, Yuki Ogimoto, Takumi Suzuki, Tomoki Kobayashi, Toshinori Ozaki, Hodaka Kurokawa, Naoto Sekiya, Ryuji Yoshida, Takeharu Kato, Tatsunori Okada, Hiroyuki Okazaki, Tetsuya Yamaki, Jens Hänisch, Satoshi Awaji, Atsutaka Maeda, Boris Maiorov, Hideo Hosono
    Nature Materials, Jul 18, 2024  Peer-reviewedLead author
    Abstract Iron-based 1111-type superconductors display high critical temperatures and relatively high critical current densities Jc. The typical approach to increasing Jc is to introduce defects to control dissipative vortex motion. However, when optimized, this approach is theoretically predicted to be limited to achieving a maximum Jc of only ∼30% of the depairing current density Jd, which depends on the coherence length and the penetration depth. Here we dramatically boost Jc in SmFeAsO1–xHx films using a thermodynamic approach aimed at increasing Jd and incorporating vortex pinning centres. Specifically, we reduce the penetration depth, coherence length and critical field anisotropy by increasing the carrier density through high electron doping using H substitution. Remarkably, the quadrupled Jd reaches 415 MA cm–2, a value comparable to cuprates. Finally, by introducing defects using proton irradiation, we obtain high Jc values in fields up to 25 T. We apply this method to other iron-based superconductors and achieve a similar enhancement of current densities.
  • Mahendra DC, Ding-Fu Shao, Vincent D.-H. Hou, Arturas Vailionis, P. Quarterman, Ali Habiboglu, M. B. Venuti, Fen Xue, Yen-Lin Huang, Chien-Min Lee, Masashi Miura, Brian Kirby, Chong Bi, Xiang Li, Yong Deng, Shy-Jay Lin, Wilman Tsai, Serena Eley, Wei-Gang Wang, Julie A. Borchers, Evgeny Y. Tsymbal, Shan X. Wang
    Nature Materials, Apr 3, 2023  Peer-reviewed
  • Masashi Miura, Go Tsuchiya, Takumu Harada, Keita Sakuma, Hodaka Kurokawa, Naoto Sekiya, Yasuyuki Kato, Ryuji Yoshida, Takeharu Kato, Koichi Nakaoka, Teruo Izumi, Fuyuki Nabeshima, Atsutaka Maeda, Tatsumori Okada, Satoshi Awaji, Leonardo Civale, Boris Maiorov
    NPG Asia Materials, 14(1), Oct 21, 2022  Peer-reviewedLead author
    Abstract The addition of artificial pinning centers has led to an impressive increase in the critical current density (Jc) of superconductors, enabling record-breaking all-superconducting magnets and other applications. The Jc of superconductors has reached ~0.2–0.3 Jd, where Jd is the depairing current density, and the numerical factor depends on the pinning optimization. By modifying λ and/or ξ, the penetration depth and coherence length, respectively, we can increase Jd. For (Y0.77Gd0.23)Ba2Cu3Oy ((Y,Gd)123), we can achieve this by controlling the carrier density, which is related to λ and ξ. We can also tune λ and ξ by controlling the chemical pressure in Fe-based superconductors, i.e., BaFe2(As1−xPx)2 films. The variation in λ and ξ leads to an intrinsic improvement in Jc via Jd, allowing extremely high values of Jc of 130 MA/cm2 and 8.0 MA/cm2 at 4.2 K, consistent with an enhancement in Jd of a factor of 2 for both incoherent nanoparticle-doped (Y,Gd)123 coated conductors (CCs) and BaFe2(As1−xPx)2 films, showing that this new material design is useful for achieving high critical current densities in a wide array of superconductors. The remarkably high vortex-pinning force in combination with this thermodynamic and pinning optimization route for the (Y,Gd)123 CCs reached ~3.17 TN/m3 at 4.2 K and 18 T (H||c), the highest values ever reported for any superconductor.
  • Sarah C. Jones, Masashi Miura, Ryuji Yoshida, Takeharu Kato, Leonardo Civale, Roland Willa, Serena Eley
    APL Materials, 9(9) 091105-091105, Sep 1, 2021  Peer-reviewed
  • Motoki Osada, Bai Yang Wang, Berit H. Goodge, Kyuho Lee, Hyeok Yoon, Keita Sakuma, Danfeng Li, Masashi Miura, Lena F. Kourkoutis, Harold Y. Hwang
    Nano Letters, 20, 5735-5740., Jul 1, 2020  Peer-reviewed
  • M.Leroux, F. F. Balakirev, M. Miura
    Phys. Rev. Applied, 11, 054005., May, 2019  Peer-reviewed
  • Serena Eley, Roland Willa, Masashi Miura, Michio Sato, Maxime Leroux, Michael David Henry, Leonardo Civale
    npj Quantum Materials, 3, 37,, Aug, 2018  Peer-reviewed
  • Masashi Miura, Boris Maiorov, Michio Sato, Motoki Kanai, Takeharu Kato, Tomohiro Kato, Teruo Izumi, Satoshi Awaji, Paolo Mele, Masaru Kiuchi, Teruo Matsushita
    NPG Asia Materials, 9, e447., Nov, 2017  Peer-reviewedLead author
    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 REBa2Cu3O7 (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 x 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.
  • S. Eley, M. Miura, B. Maiorov, L. Civale
    Nature Materials, 16, 409., Apr, 2017  Peer-reviewed
    Superconductors are excellent testbeds for studying vortices, topological excitations that also appear in superfluids, liquid crystals and Bose-Einstein condensates. Vortex motion can be disruptive; it can cause phase transitions(1), glitches in pulsars(2), and losses in superconducting microwave circuits(3), and it limits the current-carrying capacity of superconductors(4). Understanding vortex dynamics is fundamentally and technologically important, and the competition between thermal energy and energy barriers defined by material disorder is not completely understood. Specifically, early measurements of thermally activated vortex motion (creep) in iron-based superconductors unveiled fast rates (S) comparable to measurements of YBa2Cu3O7-delta (refs 5-10). This was puzzling because S is thought to somehow correlate with the Ginzburg number (Gi), and Gi is significantly lower in most iron-based superconductors than in YBa2Cu3O7-delta. Here, we report very slow creep in BaFe2(As0.67P0.33)(2) films, and propose the existence of a universal minimum realizable S similar to Gi(1/2)(T/T-c) (T-c is the superconducting transition temperature) that has been achieved in our films and few other materials, and is violated by none. This limitation provides new clues about designing materials with slow creep and the interplay between material parameters and vortex dynamics.
  • Masashi Miura, Boris Maiorov, Fedor F. Balakirev, Takeharu Kato, Michio Sato, Yuji Takagi, Teruo Izumi, Leonardo Civale
    Scientific Reports, 6, 20436., Feb, 2016  Peer-reviewedLead author
    We show a simple and effective way to improve the vortex irreversibility line up to very high magnetic fields (60T) by increasing the density of second phase BaZrO3 nanoparticles. (Y-0.77 Gd-0.23)Ba2Cu3Oy films were grown on metal substrates with different concentration of BaZrO3 nanoparticles by the metal organic deposition method. We find that upon increase of the BaZrO3 concentration, the nanoparticle size remains constant but the twin -boundary density increases. Up to the highest nanoparticle concentration (n similar to 1.3 x 10(22)/m(3)), the irreversibility field (H-irr) continues to increase with no sign of saturation up to 60T, although the vortices vastly outnumber pinning centers. We find extremely high H-irr namely H-irr = 30T (H parallel to 45 degrees) and 24T (H parallel to c) at 65 K and 58T (H parallel to 45 degrees) and 45T (H parallel to c) at 50K. The difference in pinning landscape shifts the vortex solid-liquid transition upwards, increasing the vortex region useful for power applications, while keeping the upper critical field, critical temperature and electronic mass anisotropy unchanged.
  • Masashi Miura, Boris Maiorov, Takeharu Kato, Takashi Shimode, Keisuke Wada, Seiji Adachi, Keiichi Tanabe
    NATURE COMMUNICATIONS, 4(vol.4) 2499, Sep, 2013  Peer-reviewed
    The high upper critical field and low anisotropy of the iron-based superconductor BaFe2As2 make it promising for its use in the construction of superconducting magnets. However, its critical current density in high magnetic fields needs to be improved. Here we demonstrate a simple, one-step and industrially scalable means of achieving just this. We show that introducing controlled amounts of uniformly dispersed BaZrO3 nanoparticles into carrier-doped BaFe2As2 significantly improves its superconducting performance without degrading its structural or superconducting properties. Our BaFe2(As0.66P0.33)(2) films also exhibit an increase in both the irreversibility line and critical current density at all magnetic-field orientations. These films exhibit nearly isotropic critical current densities in excess of 1.5 MA cm(-2) at 15 K and 1 T-seven times higher than previously reported for BaFe2As2 films. The vortex-pinning force in these films reaches similar to 59 GN m(-3) at 5 K and 3-9 T, substantially higher than that of the conventional Nb3Sn wire.
  • M. Miura, B. Maiorov, S. A. Baily, N. Haberkorn, J. O. Willis, K. Marken, T. Izumi, Y. Shiohara, L. Civale
    Phys. Rev. B, 83, 184519., May, 2011  Peer-reviewed
    We study the field (H) and temperature (T) dependence of the critical current density (J(c)) and irreversibility field (H-irr) at different field orientations in Y0.77Gd0.23Ba2Cu3Oy with randomly distributed BaZrO3 nanoparticles (YGdBCO + BZO) and YBa2Cu3Oy (YBCO) films. Both MOD films have large RE2Cu2O5 (225) nanoparticles (similar to 80 nm in diameter) and a high density of twin boundaries (TB). In addition, YGdBCO + BZO films have a high density of BZO nanoparticles (similar to 25 nm in diameter). At high temperatures (T > 40 K), the superconducting properties, such as J(c), H-irr, and flux creep rates, are greatly affected by the BZO nanoparticles, while at low temperatures the superconducting properties of both the YBCO and YGdBCO + BZO films show similar field and temperature dependencies. In particular, while the J(c) of YBCO films follow a power-law dependence (proportional to H-alpha) at all measured T, this dependence is only followed at low T for YGdBCO + BZO films. As a function of T, the YGdBCO + BZO film shows J(c) (T, 0.01T) similar to [1 -(T/T-c)(2)](n) with n similar to 1.24 +/- 0.05, which points to "delta T-c pinning." We analyze the role of different types of defects in the different temperature regimes and find that the strong pinning of the BZO nanoparticles yields a higher H-irr and improved J(c) along the c axis and at intermediate orientations at high T. The mixed pinning landscapes due to the presence of disorder of various dimensionalities have an important role in the improvement of in-field properties.

Books and Other Publications

 1

Research Projects

 26