Magnetism and superconductivity of some Tl-Cu oxides
Abstract
Many copper oxide based Thallium compounds are now known. In comparison to the Bi-compounds, the Tl-system shows a richer diversity; i.e., High Temperature Superconductors (HTSC) can be obtained with either one or two Tl-0 layers (m = 1,2); also, the triple-digit phases are easier to synthesize. The value of d, oxygen stoichiometry, is critical to achieving superconductivity. The Tl system is robust to oxygen loss; Tl may be lost or incorporated by diffusion. A diffusion coefficient equal to 10 ms at 900 C was determined. Both ortho-rhombic and tetragonal structures are found, but HTSC behavior is indifferent to the crystal symmetry. This system has the highest T(sub c) confirmed. T(sub c) generally increases with p, the number of CuO layers, but tends to saturate at p = 3. Zero resistance was observed at temperatures as great as 125 K. Most of these HTSC's are hole type, but the Ce-doped specimens may be electronic. The magnetic aspects were studied; because in addition to defining the perfectly diamagnetic ground state as in conventional superconductors, magnetism of the copper oxides show a surprising variety. This is true of both the normal and the superconducting states. Also, due to the large phonon contribution to the specific heat at the high T(sub c) jump, electronic density of states, D(Ef), and coherence length are uncertain, and thus, are estimated from the magnetic results. Results from the Tl-system CuO, LaBaCuO,120 and the Bi-CuO compounds are discussed. The emphasis is on the role of magnetism in the Tl-CuO HTSC, but technological aspects are also pointed out.
- Publication:
-
AMSARTS 1990: Advanced in Materials Science and Applications of High Temperature Superconductors
- Pub Date:
- January 1991
- Bibcode:
- 1991amsa.nasa..413D
- Keywords:
-
- Copper Oxides;
- Diamagnetism;
- High Temperature Superconductors;
- Magnetic Properties;
- Oxygen;
- Stoichiometry;
- Thallium Compounds;
- Diffusion Coefficient;
- Electron States;
- Ground State;
- Phonons;
- Specific Heat;
- Superconductivity;
- Solid-State Physics