Domain formation and evolution in ferroelectric materials

Malbec, Aurélien

05 1900

No description available.

Domain structure

Intrinsic magnetic aftereffect in Dy(Co,Ni)2 compounds

Carmichael, Christine Mary, Physics, Faculty of Science, UNSW

January 1981

Measurements were made of the rate of magnetization, and the magnetization of the series of Dy (Co, Ni)2 compounds to investigate the intrinsic magnetic after effect. This effect is demonstrated by the existence of an intrinsic coercivity such that a critical value of applied field, Hc, must be reached before the domain walls can move freely through the material. However there is some movement of domain walls of fields below Hc, and this gives rise to time dependent magnetization. The mechanisms by which the domain walls overcome the energy barrier to their motion at fields below Hc was investigated in pulsed field, and in steady fields. After measuring the critical field and magnetic moments of each sample, the pulsed field magnetometer results were analysed to show that there is a certain temperature above which the mechanism for domain wall motion appears to be that described by Taylor???s thermal activation model. Below that particular temperature, the magnetization rate depends on the reciprocal of the applied field, and an empirical model is suggested. Estimates are made of the number of spines contained in the average wall kink; the wall jump frequency and the energy barrier. A vibrating sample magnetometer was used to study the magnetization of the specimens in steady fields. The results indicate that both the mechanisms described above are in operation, with thermal activation being a possibility at temperatures as low as 4.2K.

Magnetism

Domain structure

The influence of defects on the domain structure and properties of ferroelectrics

Zhao, Xiaofang., 赵晓芳.

January 2011

published_or_final_version / Mechanical Engineering / Doctoral / Doctor of Philosophy

Ferroelectric crystals.

Domain structure.

Magnetic domain wall dynamics in nanoscale thin film structures

Knutson, Carl Oliver, 1980-

29 August 2008

Not available / text

Domain structure

Nanowires

Intrinsic magnetic aftereffect in Dy(Co,Ni)2 compounds

Carmichael, Christine Mary, Physics, Faculty of Science, UNSW

January 1981

Measurements were made of the rate of magnetization, and the magnetization of the series of Dy (Co, Ni)2 compounds to investigate the intrinsic magnetic after effect. This effect is demonstrated by the existence of an intrinsic coercivity such that a critical value of applied field, Hc, must be reached before the domain walls can move freely through the material. However there is some movement of domain walls of fields below Hc, and this gives rise to time dependent magnetization. The mechanisms by which the domain walls overcome the energy barrier to their motion at fields below Hc was investigated in pulsed field, and in steady fields. After measuring the critical field and magnetic moments of each sample, the pulsed field magnetometer results were analysed to show that there is a certain temperature above which the mechanism for domain wall motion appears to be that described by Taylor???s thermal activation model. Below that particular temperature, the magnetization rate depends on the reciprocal of the applied field, and an empirical model is suggested. Estimates are made of the number of spines contained in the average wall kink; the wall jump frequency and the energy barrier. A vibrating sample magnetometer was used to study the magnetization of the specimens in steady fields. The results indicate that both the mechanisms described above are in operation, with thermal activation being a possibility at temperatures as low as 4.2K.

Magnetism

Domain structure

Intrinsic magnetic aftereffect in Dy(Co, Ni)2 compounds /

Carmichael, Christine Mary.

January 1981

Thesis (Ph. D.)--University of New South Wales, 1981. / Also available online.

Magnetism. Domain structure.

Magnetic domain wall dynamics in nanoscale thin film structures

Knutson, Carl Oliver,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2008. / Vita. Includes bibliographical references.

Domain structure. Nanowires.

Physical properties of novel magnet heterostructures

Dzero, Maxim O. Gorʹkov, L. P.

January 2003

Thesis (Ph. D.)--Florida State University, 2003. / Advisor: Dr. L.P. Gorʹkov, Florida State University, Dept. of Physics. Title and description from dissertation home page (viewed Nov. 24, 2003). Includes bibliographical references.

Excitation of spin waves at magnetic domain walls /

Limaye, Pradeep Shrikrishna

January 1980

No description available.

Physics

Domain structure

Spin waves

Domain wall resonance in magnetic bubble films /

Parker, Alan A.

January 1980

No description available.

Physics

Domain structure

Magnetic resonance