Modeling ferrite electromagnetic response in the time-domain

Author

Johnson, J. ; DeFord, J.F. ; Craig, G.D.

Author_Institution

Lawrence Livermore Nat. Lab., CA, USA

fYear

1989

fDate

20-23 Mar 1989

Firstpage

1184

Abstract

It is shown that the Landau-Lifshitz-Gilbert equation can be used in conjunction with Maxwell´s equations to model the magnetization reversal process in those situations in which the nonmagnetic interactions in the material are negligible. It is seen that the resulting behavior, called uniform rotation, is characterized by intermediate magnetization states for which Δ×M&oarr;≈0, and may be described as a procession of the magnetization vector about the small demagnetizing field that is induced during the switch. The work presented is part of a broader attempt to simulate the magnetization reversal process in induction linacs. The results of a numerical simulation of the flux reversal process in an infinite cylinder with idealized boundary conditions are presented

Keywords

collective accelerators; ferrites; magnetisation reversal; Landau-Lifshitz-Gilbert equation; Maxwell´s equations; demagnetizing field; ferrite electromagnetic response; flux reversal process; induction accelerators; induction linacs; infinite cylinder; intermediate magnetization states; magnetization reversal process; magnetization vector; nonmagnetic interactions; numerical simulation; time-domain; uniform rotation; Demagnetization; Electromagnetic modeling; Ferrites; Linear accelerators; Magnetic materials; Magnetic switching; Magnetization reversal; Maxwell equations; Switches; Time domain analysis;

fLanguage

English

Publisher

ieee

Conference_Titel

Particle Accelerator Conference, 1989. Accelerator Science and Technology., Proceedings of the 1989 IEEE

Conference_Location

Chicago, IL

Type

conf

DOI

10.1109/PAC.1989.73389

Filename

73389