Transmit antenna selected spatial multiplexing systems with power allocation

Shi, Zhengyan, 1975-

January 2006

No description available.

Physics, Electricity and Magnetism.

Neutron Scattering of the Frustrated Magnets Ba2YOsO6 and Yb2Ti2O7

Maharaj, Dalini D.

January 2015

First we shall consider the rare-earth titanate Yb2Ti2O7 which has been extensively studied within the past two decades but is still not very well understood. There has been much debate over the nature of the magnetic ground state of this system with studies reporting the development of long-range order below 250mK to the absence of long-range order below 250mK. One culprit suspected of generating these differences in behaviour of the ground state is the effect of crystal growth on sample quality. In order to address this discrepancy, measurements of the crystal-field levels of Yb2Ti2O7 were conducted on two powder samples of different composition since the exact ground state selection depends on size and anisotropy of the magnetic moment. The second focus of this thesis concerns the family of rock-salt ordered double perovskites of the form Ba2YXO6 in which X is either a 4d or 5d magnetic ion. The interplay between the strong spin orbit coupling expected for such heavy magnetic ions and frustration has been theoretically predicted to exhibit a variety of exotic phenomena. Neutron scattering is utilized to investigate the low temperature dynamics of the system Ba2YOsO6 to compare with that observed in the 4d analog, Ba2YRuO6. / Thesis / Master of Science (MSc)

magnetism

frustration

neutron scattering

Spin Quantum Dynamics In Molecular Magnets

Henderson, John

01 January 2009

Molecular magnets are ideal systems to probe the realm that borders quantum and classical physics, as well as to study decoherence phenomena in nanoscale systems. The control of the quantum behavior of these materials and their structural characteristics requires synthesis of new complexes with desirable properties which will allow probing of the fundamental aspects of nanoscale physics and quantum information processing. Of particular interest among the magnetic molecular materials are single-molecule magnets (SMMs) and antiferromagnetic (AFM) molecular wheels in which the spin state of the molecule is known to behave quantum mechanically at low temperatures. In previous experiments the dynamics of the magnetic moment of the molecules is governed by incoherent quantum tunneling. Short decoherence times are mainly due to interactions between molecular magnets within the crystal and interactions of the electronic spin with the nuclear spin of neighboring ions within the molecule. This decoherence problem has imposed a limit to the understanding of the molecular spin dynamics and the sources of decoherence in condensed matter systems. Particularly, intermolecular dipolar interactions within the crystal, which shorten the coherence times in concentrated samples, have stymied progress in this direction. Several recent works have reported a direct measurement of the decoherence time in molecular magnets. This has been done by eliminating the dephasing created by dipolar interactions between neighboring molecules. This has been achieved by a) a dilution of the molecules in a liquid solution to decrease the dipolar interaction by separating the molecules, and b) by polarizing the spin bath by applying a high magnetic field at low temperatures. Unfortunately, both approaches restrict the experimental studies of quantum dynamics. For example, the dilution of molecular magnets in liquid solution causes a dispersion of the molecular spin orientation and anisotropy axes, while the large fields required to polarize the spin bath overcome the anisotropy of the molecular spin. In this thesis I have explored two methods to overcome dipolar interactions in molecular magnets: a) studying the dynamics of molecular magnets in single crystals where the separation between magnetic molecules is obtained by chemical doping or where the high crystalline quality allows observations intrinsic to the quantum mechanical nature of the tunneling of the spin, and b) studying the electronic transport through an individual magnetic molecule which has been carefully placed in a single-electron transistor device. I have used EPR microstrip resonators to measure Fe17Ga molecular wheels within single crystals of Fe18 AFM wheels, as well as demonstrating, for the first time in a Single Molecule Magnet, the complete suppression of a Quantum Tunneling of the Magnetization transition forbidden by molecular symmetry.

Molecular Magnets

magnetism

Physics

μSR and AC Susceptibility as a probe of Frustrated Pyrochlore Magnets and Type-1 Superconductivity

Beare, James Walter

January 2021

In this thesis, we use Muon Spin Rotation, Relaxation, and Resonance (μSR) as a probe for three frustrated pyrochlore systems; Gd2ScNbO7 (GSNO), Nd2ScNbO7 (NSNO) and Sm2Ti2O7 (STO), as well as the type-I superconductor BeAu. We grew all of the pyrochlore samples at McMaster using the Optical Floating Zone method. We make use of Direct Current (DC) and Alternating Current (AC) susceptibility, powder x-ray diffraction and Laue x-ray diffraction to characterize our samples. We make use of AC susceptibility measurements to explore the dynamics of the classical spin-ice Dy2Ti2O7 (DTO) and find that the system acts as a supercooled magnetic liquid, analogous to glassforming dielectric liquids. We find GSNO is a dense spin-glass based on our μSR and AC susceptibility measurements. NSNO is a moment fragmentation candidate where spin-ice, as well as all-in all-out magnetic ordering, are observed simultaneously. Our μSR measurements on this material show a strong similarity to another moment fragmentation candidate, Nd2Zr2O7, suggesting NSNO may be in a similar state. STO is a closely related compound that fully orders into a magnetic state which we study using μSR. We find subtle evidence of this magnetic transition along with persistent spin dynamics which we suggest has a common, but as of yet unexplained, origin as other frustrated pyrochlores measured in μSR. Finally, we use μSR to measure the temperature dependence of the critical field in the type-I superconductor BeAu. Using an ellipsoid of BeAu and a pressure cell, we study the magnetic properties of the sample under pressure. / Thesis / Candidate in Philosophy / In this thesis, we use Muon Spin Rotation, Relaxation, and Resonance (μSR) as a probe for three frustrated pyrochlore systems; Gd2ScNbO7 (GSNO), Nd2ScNbO7 (NSNO) and Sm2Ti2O7 (STO), as well as the type-I superconductor BeAu. We grew all of the pyrochlore samples at McMaster using the Optical Floating Zone method. We make use of Direct Current (DC) and Alternating Current (AC) susceptibility, powder x-ray diffraction and Laue x-ray diffraction to characterize our samples. We make use of AC susceptibility measurements to explore the dynamics of the classical spin-ice Dy2Ti2O7 (DTO) and find that the system acts as a supercooled magnetic liquid, analogous to glassforming dielectric liquids. We find GSNO is a dense spin-glass based on our μSR and AC susceptibility measurements. NSNO is a moment fragmentation candidate where spin-ice, as well as all-in all-out magnetic ordering, are observed simultaneously. Our μSR measurements on this material show a strong similarity to another moment fragmentation candidate, Nd2Zr2O7, suggesting NSNO may be in a similar state. STO is a closely related compound that fully orders into a magnetic state which we study using μSR. We find subtle evidence of this magnetic transition along with persistent spin dynamics which we suggest has a common, but as of yet unexplained, origin as other frustrated pyrochlores measured in μSR. Finally, we use μSR to measure the temperature dependence of the critical field in the type-I superconductor BeAu. Using an ellipsoid of BeAu and a pressure cell, we study the magnetic properties of the sample under pressure.

Frustrated Magnetism

muSR

Superconductivity

Toward Faster and Quieter MRI

Kidane, Tesfaye Kebede

15 June 2005

No description available.

Physics, Electricity and Magnetism

Calculation of Exchange and Anisotropy Energies in Single molecule magnets

Yu, Yongxue

02 December 2005

No description available.

Physics, Electricity and Magnetism

Spin Dynamics in Novel Materials Systems

Yu, Howard

08 October 2015

No description available.

Physics

Spintronics

magnetism

organic

Paramagnetic susceptibility and adiabatic demagnetization of F-centers in KCl and of chromic and ferric acetylacetonate at temperatures below 4.2ÌŠK /

Pillinger, William Lewis

January 1955

No description available.

Physics

Salts

Magnetism

Acetylacetonate

Multiple photonic responses in organic magnetic semiconductor

Yoo, Jung-Woo

05 January 2007

No description available.

Physics, Electricity and Magnetism

An experimental study of the effect of a horizontal magnetic field on the nucleate pool boiling of water and mercury with .02% Mg and .0001% Ti /

Lunardini, Virgil J.

January 1963

No description available.

Engineering

Magnetism

Heat