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A Study of High Temperature Superconductivity. With Chemical Substitutions in the 123 and 2223 Systems. Josiah Austin, Renee Catalano, Logan Finger, Robert Haag, Noah Huffman, Timothy Keebler, Madison Kratzer. PGSS 31 July 2014.
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A Study of High Temperature Superconductivity With Chemical Substitutions in the 123 and 2223 Systems Josiah Austin, Renee Catalano, Logan Finger, Robert Haag, Noah Huffman, Timothy Keebler, Madison Kratzer PGSS 31 July 2014 Background courtesy of: http://3.bp.blogspot.com/-ClOaNjbUPg8/TxBearSJARI/AAAAAAAAAbs/OwFK67eamHY/s1600/electricity.jpg
History of Superconductors • 1911- Mercury superconductor • 1933- Meissner effect • 1957- BCS theory • 1987- First high-Tc superconductor (YBa2Cu3O7) • Modern applications • MRI (Magnetic Resonance Imaging) • MagLev (Magnetic Levitation) Train • Particle accelerators Meissner effect
BCS Theory Explained • Interaction of electrons with the lattice structure - Cooper pairs • Condensation of electron velocity-space - Bose-Einstein Condensate • Energy gap - Transition temperature - Lattice vibrations • Type I vs Type II Cooper pairs interacting webs.mn.catholic.edu.au
Tested Compounds • Yttrium compounds • YBa2Cu3O7-x • Rare Earth metal substitutions • Other substitutions YBa2Cu3O7-x (courtesy of B. Mills)
Bismuth compounds • Bi2Sr2Ca2Cu3O10+x • Bi2Sr2Ca1Cu2Ox Bi2Sr2Ca2Cu3O10+x (courtesy of James Slezak)
Substitutions • Dy and Sm complete substitutions for Y in Y-123 • Sr substitutions (complete and 1 mol : 1 mol) in Y-123 • Cu doping at 90% Cu and 80% Cu using Co and Ni in Y-123 • Synthesis of Bi2Ba2Ca2Cu3Ox and Bi2Ba2CaCu2Ox using multi-phased base compound
Methods • Stoichiometry • Synthesis • Press • Firing process • 1-2-3 firing • Specialized bismuth firing • Final annealing
X-Ray Diffraction • Cathode rays • Pattern of diffraction Image courtesy of http://web.pdx.edu/~pmoeck/phy381/Topic5a-XRD.pdf
Diffraction Process https://fys.kuleuven.be/iks/nvsf/experimental-facilities/x-ray-diffraction-2013-bruker-d8-discover
Important Structures Orthorhombic Tetragonal
Resistivity • Resistivity • The ability of a substance to oppose the flow of electrons • Resistance vs. Resistivity ρ = R A/L • Resistance testing in the lab
Results (X-Ray Diffraction) • Several 1,2,3 orthorhombic structures observed • Multi-phase barium precursors formed into single phase bismuth compounds
Tetragonal Decomposition YBa(2)Cu(2.7)Co(0.3)O(7) & YBa(2)Cu(2.7)Ni(0.3)O(7)
Results (Resistivity) • Compounds that superconducted: • YBa2Cu3O7,DyBa2Cu3O7, YSrBaCu3O7 • Effects of substitutions on resistivity • Changes its critical temperature • In conducted tests, temperatures were lowered • Effects on current carrying capacity
Discussion • Successes: • Parent compound • Dysprosium substitute • Strontium (1 mol: 1 mol) doped compound • Failures: • Nickel and Cobalt partially doped for Copper • Strontium and Samarium full substitutes • Radius/Charge disparity • Bismuth substitutes • Heating problems • Sr vs. Ba http://www.berkeley.edu/news/media/releases/2004/08/16_Lanzara.shtml
Conclusions • The experiment succeeded in producing two new high-Tc superconductors, YSrBaCu3O7 and DyBa2Cu3O7. • Sources of error and limitations
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