Der magnet im alterthum,

Palm, Gustav Albert.

January 1867

Progr.--Maulbronn. 1863-1867.

Magnets.

Der magnet im alterthum

Palm, Gustav Albert.

January 1867

Progr.--Maulbronn. 1863-1867.

Magnets.

Was bleibt in einem permanenten magneten permanent? ...

Eichel, Hermann,

January 1903

Inaug.-diss.--Halle. / Lebenslauf.

Magnets.

Automating the Topological Design of Magnetic Devices

Dyck, Derek

January 1995

No description available.

Magnets

Analytical methods for electromechanical forces and torque computation in brushless permanent magnet machines /

Gangla, Vineeta,

January 1991

Thesis (M.S.)--Virginia Polytechnic Institute and State University, 1991. / Vita. Abstract. Includes bibliographical references (leaves 81-85). Also available via the Internet.

Permanent magnets

Hydrogeologic aspects of site characterization studies for underground superconductive energy storage facilities

Emanuel, Richard Paul.

January 1979

Thesis (M.S.)--University of Wisconsin--Madison. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 129-132).

Superconducting magnets.

Support system for a large superconducting magnet

Hegg, Jeffrey Wayne.

January 1978

Thesis (M.S.)--Wisconsin. / Includes bibliographical references (leaf 131).

Superconducting magnets.

Cast keepers for dental magnets : effects of laboratory procedures /

Chan, Hung-chiu, Kingsley.

January 2005

Thesis (M.D.S.)--University of Hong Kong, 2005.

Prosthodontics. Magnets

Techniques applied to the design of the TRIUMF magnet poles

Oraas, Sherman Roy

January 1970

This thesis presents some of the techniques used in designing the sector-focused magnet for the TRIUMF cyclotron. An empirical method is given for calculating the magnet pole tip shape required to contain a 500 MeV beam of H⁻ ions. The method is good only for small changes in the shape. In the test case, the generated pole tip had a spiral angle correct to within ±5 degrees, and a hill angle correct to ±1 degree. The average field was found to be isochronous to ±70 gauss. An empirical solution to the problem of finding the field inside the magnet air gap is also given. The magnetic field resulting from a given pole tip contour is calculated at a point on the median surface by finding the perpendicular distance from the point to the edge of the pole and comparing this to an experimentally measured curve of field against distance. Fields generated by this technique have their averages correct to within 70 gauss and flutter to within 8%. Again, previous knowledge of similar pole tips is assumed. The method and results of calculating the pole edge position tolerances for the latest model magnet are given. The field strengths inside the steel return yoke as obtained from a series of flux measurements are also presented. Finally, it is shown that a simple approximation to the magnetic circuit of the magnet predicts the coil induction required to an accuracy of only 25%. / Science, Faculty of / Physics and Astronomy, Department of / Graduate

Magnets.

Cyclotrons.

Thermally Driven Topology in Chiral Magnets:

Hou, Wentao

January 2019

Thesis advisor: Ziqiang . Wang / Thesis advisor: Jiadong . Zang / Magnetism is an old field in condensed matter physics, but it is still vibrant and full of excitement. Regardless of deep fundamental physics therein, it also has broad application in engineering technology, modern hard disk drive as an example. Magnetic skyrmion, a vortex-like structure in two-dimensional magnetic systems, has been discovered in various magnetic materials, among which chiral magnets are a family of candidates. The skyrmions are characterized by nonzero topological charges. The vortex-like structure of skyrmions makes skyrmion materials good candidates of new generation of data storage device. So understanding the transport properties of the skyrmion materials is important for the possible application in the future. The Hall effect is a key aspect of electron transports. The topological Hall effect, which is one component in the total Hall effect, only depends on the magnetic structures, and the topological Hall conductivity is proportional to the topological charge. It thus serves as the transport signature of magnetic skyrmions. The major mission of this thesis is to investigate the topological charge distribution in realistic models and uncover the relationship between the existence of skyrmions and other chiral excitations. The organization of the thesis is the following. The first chapter is the introduction. A historical survey about magnetic skyrmions and chiral magnets is presented firstly. The magnetic skyrmion is identified by the topological charge. Further, the relationship between the topological hall effect and topological charge is described by the emergent electrodynamics. The importance of the topological charge in chiral magnets is explained in this part. Following the importance of the topological charge, the investigation of topological charge in two-dimensional chiral magnets is presented in the second chapter. The Monte Carlo simulation is employed to calculate the topological charge on a square lattice. The results show that the nonzero topological charge is not necessarily correlated to the existence of skyrmions in chiral magnets. To understand the numerical results, simple analysis based on the physical picture of a triangle on the square lattice is performed. Then we calculate the topological charge in continuum model of chiral magnets. At the high temperature limit, the numerical results, picture analysis and the analytic result are consistent. Then, in this chapter, there is a description of the recent experimental work on thin film SrRuO3 which confirmed our theoretical prediction. A discussion on spin chirality, topological charge and Hall conductivity is presented in the end. However, no experiment on chiral magnets has been on a perfect monolayer system. So we extend the investigation of topological charge into three-dimensional situation. This work is introduced in the third chapter. The Monte Carlo simulation and the analytical calculation are presented firstly. A special issue in three-dimensional chiral magnets is the thickness dependence. The Monte Carlo simulation is used to address this issue. A combination of analytical calculation and physical picture of magnons is used to explain the numerical results well. Similar as the second chapter, the experiment on finite thickness SrRuO3 is described. Because the effective Dzyaloshinskii—Moriya interaction is due to the interface effect which cannot be used to judge our numerical results based on homogenous chiral magnets. The Heisenberg interaction in the system described in the previous two chapters is ferromagnetic interaction. More physical results with antiferromagnetic interaction are expected in different magnetic system. In the fourth chapter, a review of the work on a frustrated magnet with hexagonal lattice is introduced. The direction of the DM interaction of the hexagonal lattice is perpendicular to the bonds of nearest magnetic atoms. The topological charge is calculated numerically. A similar thermally driven topology as found in chiral magnets is achieved by investigating the topological charge. Following that, the system with staggered DM interaction is discussed. The study of the topological charge in this system not only gives the evolution of thermally driven topology of the system, but also distinguishes the topological charge and spin chirality based on the antiferromagnetic interaction. Not only thermally driven topology in chiral magnets but also the driven motion of skyrmions are interesting to us. Inspired by the similarity of the vortex state in the Type-II superconductor and skyrmion crystal phase, we investigate the proximity effect between the skyrmion material and non-centrosymmetric s-wave superconductor. The method is to calculate the effective interaction between the Cooper pairs and skyrmions. A field-theoretical approach is employed to this end. / Thesis (PhD) — Boston College, 2019. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Physics.

Chiral magnets