화학공학소재연구정보센터
Korean Journal of Materials Research, Vol.23, No.6, 309-315, June, 2013
고상반응법으로 합성한 분말로부터 Gd1.5Ba2Cu3O7-y 벌크 초전도체의 제조
Fabrication of Gd1.5Ba2Cu3O7-y Bulk Superconductors from the Powder Synthesized by a Solid-State Reaction Method
E-mail:
GdBa2Cu3O7-y(Gd123) powders were synthesized by the solid-state reaction method using Gd2O3 (99.9% purity), BaCO3 (99.75%) and CuO (99.9%) powders. The synthesized Gd123 powder and the Gd123 powder with Gd2O3 addition (Gd1.5Ba2Cu3O7-y(Gd1.5)) were used as raw powders for the fabrication of Gd123 bulk superconductors. The Gd123 and Gd1.5 bulk superconductors were fabricated by sintering or a top-seeded melt growth (TSMG) process. The superconducting transition temperature (Tc,onset) of the sintered Gd123 was 93 K and the transition width was as large as 20 K. The Tc,onset of the TSMG processed Gd123 was 82 K and the transition width was also as large as 12 K. The critical current density (Jc) at 77 K and 0 T of the sintered Gd123 and TSMG processed Gd123 were as low as a few hundreds A/cm2. The addition of 0.25 mole Gd2O3 and 1 wt.% CeO2 to Gd123 enhanced the Tc, Jc and magnetic flux density (H) of the TSMG processed Gd123 sample owing to the formation of the superconducting phase with high flux pinning capability. The Tc of the TSMG processed Gd1.5 was 92 K and the transition width was 1 K. The Jcs at 77 K (0 T and 2 T) were 3.2 × 104 A/cm2 and 2.5 × 104 A/cm2, respectively. The H at 77 K of the TSMG-processed Gd1.5 was 1.96 kG, which is 54% of the applied magnetic field (3.45 kG).
  1. Wu MK, Ashburn JR, Thorng CJ, Hor PH, Meng RL, Gao L, Huang ZJ, Wang Q, Chu CW, Phys. Rev. Lett., 58, 908 (1987)
  2. Matsunaga K, Tomita M, Yamachi N, Iida K, Yoshioka J, Murakami M, Supercond. Sci. Technol., 15, 842 (2002)
  3. Nagashima K, Higuchi T, Sok J, Yoo SI, Fujimoto H, Murakami M, Cryogenics, 37, 577 (1997)
  4. Hayashi H, Tsutsumi K, Saho N, Nishizima N, Asano K, Physica C, 392-396, 745 (2003)
  5. Murakami M, Sakai N, Higuchi T, Yoo SI, Supercond. Sci. Technol., 9, 1015 (1996)
  6. Cardwell DA, Hari Babu N, Physica C, 445-448, 1 (2006)
  7. Haugan T, Barnes PN, Wheeler R, Meisenkothen F, Sumption M, Nature, 430, 867 (2004)
  8. Salamati H, Babaei-Brojeny A, Safa M, Supercond. Sci. Technol., 14, 816 (2001)
  9. Kim CJ, Lee HG, Kuk IH, Chang IS, Rim CS, Han PS, Won DY, J. Mater. Sci., 25, 2165 (1990)
  10. Shin MW, Kingon AI, Hare TM, Koch CC, Mater. Lett., 15, 13 (1992)
  11. Jee YA, Kim CJ, Sung TH, Hong GW, Supercond. Sci. Technol., 13, 195 (2000)
  12. Kim CJ, Kim HJ, Joo JH, Hong GW, Han SC, Han YH, Sung TH, Kim SJ, Physica C,, 336, 233 (2000)
  13. Kim CJ, Hong GW, Supercond. Sci. Technol., 12, R27 (1999)
  14. Murakami M, Mod. Phys. Lett., B, 4, 163 (1990)
  15. Kim CJ, Kim KB, Kuk IH, Hong GW, Lee YS, Park HS, Supercond. Sci. Technol., 10, 947 (1997)
  16. Kishio K, Shimoyama J, Hasegawa T, Kitazawa K, Fueki K, Jpn. J. Appl. Phys., 26, L1228 (1987)
  17. Bean CP, Rev. Mod. Phys., 36, 446 (1964)
  18. Lee JH, Zhang X, Wang H, J. Appl. Phys., 109, 083510 (2011)
  19. Zhang K, Dabrowski B, Segre CU, Hinks DG, Schuller IK, Jorgensen JD, Slaski M, J. Phys. C:Solid State Phys., 20, L935 (1987)
  20. Yoo SI, Sakai N, Taguchi H, Murakami M, Appl. Phys. Lett., 65, 633 (1994)
  21. Ling XS, Budnick JI, Vea BW, Physica C, 282-287, 2191 (1997)