On nanoferroelectric domain structures and distributions of defects inferroelectrics

Hong, Liang, 洪亮

January 2010

published_or_final_version / Mechanical Engineering / Doctoral / Doctor of Philosophy

Ferroelectric crystals.

Domain structure.

Nanostructured materials.

Theory of the structure of ferromagnetic domains in films and small particles

January 1946

[by] Charles Kittel. / "Reprinted from the Physical review, vol. 70, nos. 11 and 12, 965-971, Dec. 1 and 15, 1946." / Includes bibliographical references.

TK7855.M41 R43 no.16

Domain structure

Field-driven and spin-transfer-torque-driven domain-wall dynamics in permalloy micro-/nano-structures

Yang, Shuqiang, 1973-

29 August 2008

This dissertation explores magnetic-field- and electric-current-driven domain-wall motion in thin-film-based magnetic microstructures. Conventional thin-film growth and microstructure fabrication techniques including electron-beam lithography and focused ion beam milling are used to fabricate nanometer-scale one-dimensional and two-dimensional magnetic structures that support magnetic domains (regions of different magnetization orientation separated by domain walls). A high-spatial resolution, hightemporal resolution technique for measuring the field- or current- driven dynamics of the domain walls, based on the magneto-optic Kerr effect, is developed and used to study the wall dynamics. Field-driven domain-wall motion at slow magnetic field sweep rates is dominated by Barkhausen jumps, the discontinuous random movement of domain-wall displacements. The experiments described represent one of the first successful attempts to extend the study of Barkhausen effects into the two-dimensional region. The experiments successfully probe velocity distributions, jump amplitude distributions, and attempt to address issues that pertain to the universal exponents that describe the scaling behavior of Barkhausen jump distribution function including effects of dimensionality and sweep-rate effects on the exponents. A novel dual-beam magneto-optical experiment is performed on thin-film microstructure that probes negative Barkhausen jumps (jumps that oppose the direction favored by Zeeman energy driving the magnetic reversal). A new mechanism for negative Barkhausen jumps is proposed that accounts for the observed effects. Domain-wall motion driven by (spin-polarized) electric current is studied in nanoscale thin-film based wires. The experiments address issues pertaining to the basic mechanisms responsible for current-driven domain-wall motion, which are believed to be the adiabatic spin-torque mechanism and non-adiabatic mechanisms. The experiments described are the first true time-resolved measurements of current-driven displacements, and the results reveal new information about the stochastic properties of current-driven domain wall displacements. The results also provide information on domain-wall velocities and spin-flip efficiencies that address issues related to spin-torque mechanisms.

Domain structure

Magnetic materials

Thin films

Field-driven and spin-transfer-torque-driven domain-wall dynamics in permalloy micro-/nano-structures

Yang, Shuqiang,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2007. / Vita. Includes bibliographical references.

Confocal luminescence microscopy study of defect-domain wall interaction in LiNbO₃ and its application to light-induced domain engineering /

Sandmann, Christian,

January 2004

Thesis (Ph. D.)--Lehigh University, 2005. / Includes vita. Includes bibliographical references (leaves 177-190).

On nanoferroelectric domain structures and distributions of defects in ferroelectrics

Hong, Liang,

January 2010

Thesis (Ph. D.)--University of Hong Kong, 2010. / Includes bibliographical references (leaves 104-128). Also available in print.

Surface pole modeling of field access magnetic bubble devices

Lai, Fang-Shi Jordan,

January 1980

Thesis (Ph. D.)--University of Florida, 1980. / Description based on print version record. Typescript. Vita. Includes bibliographical references (leaves 143-146).

The application of frequency domain techniques in the multivariable modelling and control of an airframe

Muller, Rocco Martin

04 June 2014

M.Ing. (Electrical and Electronic Engineering) / This treatise presents an investigation into the application of multivariable frequency domain techniques in the modelling and control of a helicopter aircraft in forward flight. The presentation is structured in the following sectioned format: I Hypotheses are stated which deal with the use of linear, multivariable, frequency domain theory in the modelling and control of helicopter aircraft. II The stated hypotheses are investigated by the application of relevant theories and techniques to a reference case plant - a single rotor helicopter in forward flight. III Conclusions drawn from the results are used to assess the validity of the hypotheses. The subject matter of the presentation may be summarized as follows: The hypotheses are initially placed in perspective by a discussion of the incentives for their formulation. In essence, the hypotheses state that helicopter dynamics, in a multivariable systems characterization, can be modelled and an appropriate flight control system designed by the use of linear frequency domain theory. The plant in reference to which the hypotheses are investigated is a single rotor utility helicopter - the Aerospatiale Alouette III. A single flight condition - a typical cruising condition - is considered. A comprehensive, nonlinear digital computer simulation of the aircraft is used as a substitute for the actual plant in the execution of the modelling and control design processes. The plant is modelled in terms of a linear model structure, in the form of the frequency response function, by linearization of its highly nonlinear dynamics about an operating point (datum flight condition). The frequency response function model parameters are identified by power spectral density analysis procedures. This method, based on random signal excitation of the plant, provides a valuable quantitative measure of the accuracy of the linearization performed in the identification. The measure, the coherence function, is used as a criterion for the robustness required of a control system of which the design is based on a linear model of a nonlinear plant.

Airframes

Domain structure

Rotors (Helicopters)

Stochastic processes

Domain wall resonance in magnetic garnet thin film and the associated acoustic phenomena /

Yeh, Ren-jye

January 1982

No description available.

Physics

Domain structure

Magnetic resonance

Garnet

Coupled oscillations of the magnetic domain-domain wall system in substituted garnet thin films /

Ramesh, Mahadevan

January 1986

No description available.

Physics

Domain structure

Magnetic resonance

Garnet

Oscillations