Your search keyword '"Bag R"' showing total 6 results

1. Magnetic phase diagram, magnetoelastic coupling, and Grüneisen scaling in CoTiO3

Author

Hoffmann, M., Dey, K., Werner, J., Bag, R., Kaiser, J., Wadepohl, H., Skourski, Y., Abdel-Hafiez, Mahmoud, Singh, S., Klingeler, R., Hoffmann, M., Dey, K., Werner, J., Bag, R., Kaiser, J., Wadepohl, H., Skourski, Y., Abdel-Hafiez, Mahmoud, Singh, S., and Klingeler, R.

Abstract

High-quality single crystals of CoTiO3 are grown and used to elucidate in detail structural and magnetostructural effects by means of high-resolution capacitance dilatometry studies in fields up to 15 T which are complemented by specific heat and magnetization measurements. In addition, we refine the single-crystal structure of the ilmenite (R (3) over bar) phase. At the antiferromagnetic ordering temperature T-N pronounced lambda-shaped anomaly in the thermal expansion coefficients signals shrinking of both the c and b axes, indicating strong magnetoelastic coupling with uniaxial pressure along c yielding six times larger effect on T-N than pressure applied in-plane. The hydrostatic pressure dependency derived by means of Gruneisen analysis amounts to partial derivative T-N/partial derivative p approximate to 2.7(4) K/GPa. The high-field magnetization studies in static and pulsed magnetic fields up to 60 T along with high-field thermal expansion measurements facilitate in constructing the complete anisotropic magnetic phase diagram of CoTiO3. While the results confirm the presence of significant magnetodielectric coupling, our data show that magnetism drives the observed structural, dielectric, and magnetic changes both in the short-range ordered regime well above T-N as well as in the long-range magnetically ordered phase., De två första författarna delar förstaförfattarskapet.

Published

2021

2. Magnetic phase diagram and magnetoelastic coupling of NiTiO3

Author

Dey, K., Sauerland, S., Werner, J., Scurschii, I., Abdel-Hafiez, M., Bag, R., Singh, S., Klingeler, R., Dey, K., Sauerland, S., Werner, J., Scurschii, I., Abdel-Hafiez, M., Bag, R., Singh, S., and Klingeler, R.

Abstract

We report high-resolution dilatometry on high-quality single crystals of NiTiO3 grown by means of the optical floating-zone technique. The anisotropic magnetic phase diagram is constructed from thermal expansion and magnetostriction studies up toB=15 T and magnetization studies in static (15-T) and pulsed (60-T) magnetic fields. Our data allow us to quantitatively study magnetoelastic coupling and to determine uniaxial pressure dependencies. While the entropy changes are found to be of magnetic nature, Grüneisen analysis implies only one relevant energy scale in the whole low-temperature regime. Thereby, our data suggest that the observed structural changes due to magnetoelastic coupling and previously reported magnetodielectric coupling [L. Balhorn, J. Hazi, M. C. Kemei, and R. Seshadri, Phys. Rev. B93, 104404(2016)] are driven by the same magnetic degrees of freedom that lead to long-range magnetic order in NiTiO3.

Published

2020

3. Magnetic phase diagram and magnetoelastic coupling of NiTiO3

Author

Dey, K., Sauerland, S., Werner, J., Scurschii, I., Abdel-Hafiez, M., Bag, R., Singh, S., Klingeler, R., Dey, K., Sauerland, S., Werner, J., Scurschii, I., Abdel-Hafiez, M., Bag, R., Singh, S., and Klingeler, R.

Abstract

We report high-resolution dilatometry on high-quality single crystals of NiTiO3 grown by means of the optical floating-zone technique. The anisotropic magnetic phase diagram is constructed from thermal expansion and magnetostriction studies up toB=15 T and magnetization studies in static (15-T) and pulsed (60-T) magnetic fields. Our data allow us to quantitatively study magnetoelastic coupling and to determine uniaxial pressure dependencies. While the entropy changes are found to be of magnetic nature, Grüneisen analysis implies only one relevant energy scale in the whole low-temperature regime. Thereby, our data suggest that the observed structural changes due to magnetoelastic coupling and previously reported magnetodielectric coupling [L. Balhorn, J. Hazi, M. C. Kemei, and R. Seshadri, Phys. Rev. B93, 104404(2016)] are driven by the same magnetic degrees of freedom that lead to long-range magnetic order in NiTiO3.

Published

2020

4. Magnetic phase diagram and magnetoelastic coupling of NiTiO3

Author

Dey, K., Sauerland, S., Werner, J., Scurschii, I., Abdel-Hafiez, M., Bag, R., Singh, S., Klingeler, R., Dey, K., Sauerland, S., Werner, J., Scurschii, I., Abdel-Hafiez, M., Bag, R., Singh, S., and Klingeler, R.

Abstract

We report high-resolution dilatometry on high-quality single crystals of NiTiO3 grown by means of the optical floating-zone technique. The anisotropic magnetic phase diagram is constructed from thermal expansion and magnetostriction studies up toB=15 T and magnetization studies in static (15-T) and pulsed (60-T) magnetic fields. Our data allow us to quantitatively study magnetoelastic coupling and to determine uniaxial pressure dependencies. While the entropy changes are found to be of magnetic nature, Grüneisen analysis implies only one relevant energy scale in the whole low-temperature regime. Thereby, our data suggest that the observed structural changes due to magnetoelastic coupling and previously reported magnetodielectric coupling [L. Balhorn, J. Hazi, M. C. Kemei, and R. Seshadri, Phys. Rev. B93, 104404(2016)] are driven by the same magnetic degrees of freedom that lead to long-range magnetic order in NiTiO3.

Published

2020

5. Magnetic phase diagram and magnetoelastic coupling of NiTiO3

Author

Dey, K., Sauerland, S., Werner, J., Scurschii, I., Abdel-Hafiez, M., Bag, R., Singh, S., Klingeler, R., Dey, K., Sauerland, S., Werner, J., Scurschii, I., Abdel-Hafiez, M., Bag, R., Singh, S., and Klingeler, R.

Abstract

We report high-resolution dilatometry on high-quality single crystals of NiTiO3 grown by means of the optical floating-zone technique. The anisotropic magnetic phase diagram is constructed from thermal expansion and magnetostriction studies up toB=15 T and magnetization studies in static (15-T) and pulsed (60-T) magnetic fields. Our data allow us to quantitatively study magnetoelastic coupling and to determine uniaxial pressure dependencies. While the entropy changes are found to be of magnetic nature, Grüneisen analysis implies only one relevant energy scale in the whole low-temperature regime. Thereby, our data suggest that the observed structural changes due to magnetoelastic coupling and previously reported magnetodielectric coupling [L. Balhorn, J. Hazi, M. C. Kemei, and R. Seshadri, Phys. Rev. B93, 104404(2016)] are driven by the same magnetic degrees of freedom that lead to long-range magnetic order in NiTiO3.

Published

2020

6. Behaviour of compacted MX80 bentonite under thermo-hydraulic gradients

Author

Datta M Ramana G, Srivastava R K, Bag, R., Tripathy, Snehasis, Thomas, H. R., Datta M Ramana G, Srivastava R K, Bag, R., Tripathy, Snehasis, and Thomas, H. R.