S. Jemima Balaselvi scite author profile

Successful replacement of B by C in the series MgB 2-x C x for values of x upto 0.3 are reported. Resistivity and ac susceptibility measurements have been carried out in the samples. Solubility of carbon, inferred from the observed change in the lattice parameter with carbon content indicates that carbon substitutes upto x=0.30 into the MgB 2 lattice. The superconducting transition temperature, T C measured both by zero resistivity and the onset of the diamagnetic signal shows a systematic decrease with increase in carbon content upto x=0.30, beyond which the volume fraction decreases drastically. The temperature dependence of resistivity in the normal state fits to the Bloch-Gruneisen formula for all the carbon compositions studied. The Debye temperatures, θ D , extracted from the fit is seen to decrease with carbon content from 900K to 525K, whereas the electron-phonon interaction parameter, λ, obtained from the McMillan equation using the measured T C and θ D , is seen to increase monotonically from 0.8 in MgB 2 to 0.9 in the x=0.50 sample. The ratio of the resistivities between 300K and 40K versus T C is seen to follow the Testardi correlation for the C substituted samples. The decrease in T C is argued to mainly arise due to large decrease in θ D with C concentration and a decrease in the hole density of states at N(E F ).

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Synthesis and search for superconductivity in LiBC

Bharathi

Balaselvi

Premila

et al. 2002

Solid State Communications

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Following the recent theoretical prediction of superconductivity in hole doped LiBC by Rosner et al [1], we have attempted to synthesise Li deficient Li x BC ( x = 1, 0.8, 0.6 and 0.4) and look for superconductivity in this system. Our synthesis procedure, following the recipe for MgB 2 , involves reaction of elemental components in a Ta crucible at 900o C under 50 bar of argon pressure. X-ray diffraction measurements indicate the formation of P6 3 /mmc structure up to x=0.6. However, no diamagnetic signal or zero resistance, corresponding to the superconducting transition, was observed in the temperature range of 300 to 4 K. This is possibly related to the presence of disorder in the B-C stacking; evidence for which is suggested from a study of the vibrational modes of Li x BC through infrared spectroscopy.

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Stoichiometric carbon substitution in MgB₂

Balaselvi

Gayathri

Bharathi³

et al. 2004

Supercond. Sci. Technol.

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Carbon has been substituted into the MgB2 lattice, forming the series Mg(B1−xCx)2, by heat treatments in sealed Ta tubes starting with elemental constituents. The superconducting transition temperature, TC, was measured by diamagnetic susceptibility. The superconducting transitions are sharp and the x-ray diffraction on the samples show only trace amounts of impurity phases. The C fraction that substitutes the B atoms into the MgB2 lattice, as determined from the now well established correlation between the ‘a’ lattice parameter and x in Mg(B1−xCx)2 is found to be very close to the targeted values. The temperature dependence of the normalized resistance is similar to that seen in C doped MgB2 single crystals along the ab plane. Rn/R(300 K), where Rn is the resistance just above TC, increases with x.

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Peculiarities in the carbon substitution of MgB2

Balaselvi

Gayathri

Bharathi

et al. 2004

Physica C: Superconductivity

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Effect of electron and hole doping on the superconducting and normal state properties of MgB2

Balaselvi¹,

Bharathi²,

Sastry³

et al. 2002

Preprint

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