High frequency design and EMR

Author

Bender, Christopher J.

Author_Institution

Einstein Coll. of Med., USA

Volume

17

Issue

1

fYear

1998

Firstpage

13

Lastpage

16

Abstract

Nuclear magnetic resonance (NMR) is a form of radio frequency (RF) spectroscopy. Its current popularity in applications, such as analytical chemistry and biomedical imaging was made possible by advances in RF design. Those advances permitted modern pulsed excitation and data acquisition in the microsecond time domain. Electron magnetic resonance (EMR) is equally powerful. But, its timescale for the spin dynamics (subnanosecond) and excitation spectrum (microwave) have posed formidable technological problems. These problems have forced the method to lag behind NMR. The situation is changing rapidly, however. Improvements in high frequency design now allow EMR to sit at an evolutionary threshold. These improvements and various technological solutions are considered. The processes involved in EMR are also discussed

Keywords

EPR spectroscopy; microwave generation; microwave spectroscopy; radiofrequency spectroscopy; EMR; RF design; analytical chemistry; biomedical imaging; data acquisition; electron magnetic resonance; excitation spectrum; high frequency design; high-power nanosecond microwave pulses; microsecond time domain; nuclear magnetic resonance; pulsed excitation; radio frequency spectroscopy; spin dynamics; timescale; Biochemical analysis; Biomedical imaging; Chemistry; Data acquisition; Electrons; Image analysis; Magnetic analysis; Nuclear magnetic resonance; Radio frequency; Spectroscopy;

fLanguage

English

Journal_Title

Potentials, IEEE

Publisher

ieee

ISSN

0278-6648

Type

jour

DOI

10.1109/45.652850

Filename

652850