Low-pressure conversion studies for YBCO precursors derived by PVD and MOD methods

F. A. List; P. G. Clem; L. Heatherly; J. T. Dawley; K. J. Leonard; D. F. Lee; A. Goyal

doi:10.1109/TASC.2005.847760

Low-pressure conversion studies for YBCO precursors derived by PVD and MOD methods

F. A. List, P. G. Clem, L. Heatherly, J. T. Dawley, K. J. Leonard, D. F. Lee, A. Goyal

Deposition Science and Technology

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

The rate at which thin film YBCO precursor converts to high J_c superconductor depends on many factors including the method by which the precursor is prepared, the precursor film thickness, and the conditions during precursor deposition and conversion. Using in-situ X-ray diffraction and reduced pressures, we have examined and compared conversion rates for precursors prepared by physical vapor deposition (PVD) and metal-organic deposition (MOD). For conversion conditions found to be optimal for obtaining high J_c and high precursor conversion rate (G_p) for PVD precursors, the G_p is nearly identical (∼0.2 nm/sec) for the both PVD and MOD precursors. The development of crystalline BaF₂ is, however, distinctly different for the two precursors. This may suggest that conversions of these PVD and MOD precursors follow different chemical pathways. For both precursors, higher G_p is realized using higher water pressure and ramp rate. Although G_p is higher, YBCO is randomly oriented and J_c is zero for the PVD precursor. The MOD precursor seems to be generally more tolerant of higher reaction rates than the PVD precursor. The reaction rate versus P_H2O determined for both precursor types shows a square root of P_H2O dependence of G_p. This behavior is consistent with a reaction rate limited by gas-phase HF removal.

Original language	English
Pages (from-to)	2656-2658
Number of pages	3
Journal	IEEE Transactions on Applied Superconductivity
Volume	15
Issue number	2 PART III
DOIs	https://doi.org/10.1109/TASC.2005.847760
State	Published - Jun 2005

Funding

Manuscript received October 4, 2004. This research was sponsored by the United States Department of Energy, Office of Electric Transmission and Distribution—Superconductivity program under contracts DE-AC05-00OR22725 (ORNL) and DE-AC04-94AL85000 (SNL). F. A. List, L. Heatherly, K. J. Leonard, D. F. Lee, and A. Goyal are at Oak Ridge National Laboratory, Oak Ridge, TN 37831 USA (e-mail: [email protected]). P. G. Clem and J. T. Dawley are at Sandia National Laboratories, Albuquerque, NM 87185 USA. Digital Object Identifier 10.1109/TASC.2005.847760

Keywords

Precursor conversion
Reaction kinetics
Superconducting tapes

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10.1109/TASC.2005.847760

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title = "Low-pressure conversion studies for YBCO precursors derived by PVD and MOD methods",

abstract = "The rate at which thin film YBCO precursor converts to high Jc superconductor depends on many factors including the method by which the precursor is prepared, the precursor film thickness, and the conditions during precursor deposition and conversion. Using in-situ X-ray diffraction and reduced pressures, we have examined and compared conversion rates for precursors prepared by physical vapor deposition (PVD) and metal-organic deposition (MOD). For conversion conditions found to be optimal for obtaining high Jc and high precursor conversion rate (Gp) for PVD precursors, the Gp is nearly identical (∼0.2 nm/sec) for the both PVD and MOD precursors. The development of crystalline BaF2 is, however, distinctly different for the two precursors. This may suggest that conversions of these PVD and MOD precursors follow different chemical pathways. For both precursors, higher Gp is realized using higher water pressure and ramp rate. Although Gp is higher, YBCO is randomly oriented and Jc is zero for the PVD precursor. The MOD precursor seems to be generally more tolerant of higher reaction rates than the PVD precursor. The reaction rate versus PH2O determined for both precursor types shows a square root of PH2O dependence of Gp. This behavior is consistent with a reaction rate limited by gas-phase HF removal.",

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AU - Clem, P. G.

AU - Heatherly, L.

AU - Dawley, J. T.

AU - Leonard, K. J.

AU - Lee, D. F.

AU - Goyal, A.

PY - 2005/6

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N2 - The rate at which thin film YBCO precursor converts to high Jc superconductor depends on many factors including the method by which the precursor is prepared, the precursor film thickness, and the conditions during precursor deposition and conversion. Using in-situ X-ray diffraction and reduced pressures, we have examined and compared conversion rates for precursors prepared by physical vapor deposition (PVD) and metal-organic deposition (MOD). For conversion conditions found to be optimal for obtaining high Jc and high precursor conversion rate (Gp) for PVD precursors, the Gp is nearly identical (∼0.2 nm/sec) for the both PVD and MOD precursors. The development of crystalline BaF2 is, however, distinctly different for the two precursors. This may suggest that conversions of these PVD and MOD precursors follow different chemical pathways. For both precursors, higher Gp is realized using higher water pressure and ramp rate. Although Gp is higher, YBCO is randomly oriented and Jc is zero for the PVD precursor. The MOD precursor seems to be generally more tolerant of higher reaction rates than the PVD precursor. The reaction rate versus PH2O determined for both precursor types shows a square root of PH2O dependence of Gp. This behavior is consistent with a reaction rate limited by gas-phase HF removal.

AB - The rate at which thin film YBCO precursor converts to high Jc superconductor depends on many factors including the method by which the precursor is prepared, the precursor film thickness, and the conditions during precursor deposition and conversion. Using in-situ X-ray diffraction and reduced pressures, we have examined and compared conversion rates for precursors prepared by physical vapor deposition (PVD) and metal-organic deposition (MOD). For conversion conditions found to be optimal for obtaining high Jc and high precursor conversion rate (Gp) for PVD precursors, the Gp is nearly identical (∼0.2 nm/sec) for the both PVD and MOD precursors. The development of crystalline BaF2 is, however, distinctly different for the two precursors. This may suggest that conversions of these PVD and MOD precursors follow different chemical pathways. For both precursors, higher Gp is realized using higher water pressure and ramp rate. Although Gp is higher, YBCO is randomly oriented and Jc is zero for the PVD precursor. The MOD precursor seems to be generally more tolerant of higher reaction rates than the PVD precursor. The reaction rate versus PH2O determined for both precursor types shows a square root of PH2O dependence of Gp. This behavior is consistent with a reaction rate limited by gas-phase HF removal.

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Low-pressure conversion studies for YBCO precursors derived by PVD and MOD methods

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