Magnetic Resonance and Its Applications / by Vladimir I. Chizhik, Yuri S. Chernyshev, Alexey V. Donets, Vyacheslav V. Frolov, Andrei V. Komolkin, Marina G. Shelyapina.

Format:

Book

Author/Creator:

Chizhik, Vladimir I., author.

Chernyshev, Yuri S., author.

Donets, Alexey V., author.

Frolov, Vyacheslav V., author.

Komolkin, Andrei V., author.

Shelyapina, Marina G., author.

Contributor:

SpringerLink (Online service)

Language:

English

Subjects (All):

Medicine.

Physical organic chemistry.

Magnetism.

Physical Description:

1 online resource : color illustration

Contained In:

Springer eBooks

Place of Publication:

Cham : Springer International Publishing : Imprint: Springer, 2014.

System Details:

Mode of access: World Wide Web.

text file PDF

Summary:

The book is devoted to the description of the fundamentals of various radiospectroscopic methods in the area of magnetic resonance and their use for the investigation of molecular structure and dynamics and for some technical applications. This book covers two domains: radiospectroscopy and quantum radioelectronics. Radiospectroscopy comprises nuclear magnetic resonance (NMR), electron paramagnetic resonance (EPR), nuclear quadrupolar resonance (NQR), and some other phenomena. The radiospectroscopic methods are widely used for obtaining the information on internal (micro and macro) structure of objects investigated. There are no direct analogues of magnetic relaxation processes among the physical phenomena that define spectra in infrared, visible and higher frequency spectroscopy. Relaxation parameters are directly related to molecular mobility and thus represent an unique source of information on velocity and types of thermal motion. One of the most spectacular developments is the concept of double (multi) resonances (NMR-ESR, NMR-NQR, NMR-NMR and so on). Quantum radioelectronics, which was developed on the basis of radiospectroscopic methods, deals with processes in quantum amplifiers, generators and magnetometers. These devices possess record-breaking characteristics: quantum generators demonstrate the highest frequency stability; quantum amplifiers possess the lowest level of set noise; quantum magnetometers are very fruitful tool for measuring weak magnetic fields (such as the Earth field). The introductory chapter provides the necessary underpinning knowledge for newcomers to the methods. The exposition of theoretical materials goes from initial to final formulas through detailed intermediate expressions.

Contents:

Interaction between nuclei and electrons and their interaction with external electromagnetic fields

Part I Nuclear magnetic resonance (NMR)

Basic principles of detection of nuclear magnetic resonance

Nuclear magnetic relaxation

Nuclear Magnetic Resonance in Liquids

Nuclear magnetic resonance in diamagnetic solids

Nuclear Magnetic Resonance in Liquid Crystals

Nuclear magnetic resonance in magnetic materials

Part II Nuclear quadrupole resonance (NQR)

Nuclear quadrupole resonance

Experimental methods in NQR

Part III Electron paramagnetic resonance (EPR)

Basic interactions of an electron in solids

Energy levels of paramagnetic center in crystal field

Covalent-coupled paramagnetic

Fine structure of EPR spectra in solids

Electron-nuclear interactions and hyperfine structure of EPR spectra

Part IV Double resonances and polarization transfer

Double resonances

Two-dimensional NMR Fourier spectroscopy

Part V Quantum radiofrequency electronics (radioelectronics)

Basic physical ideas of quantum radioelectronics

Generators with molecular and atomic beams

Quantum amplifiers based on electron paramagnetic resonance

The use of optical radiation in quantum radioelectronics devices

Magnetic resonance quantum magnetometry.

ISBN:

9783319052991

Access Restriction:

Restricted for use by site license.