Conversion of Gaussian to SI Units: To obtain values in SI units, multiply the value in Gaussian units by the respective ratio. The book "Principles of Magnetic Resonance" by Charles P. Slichter, third enlarged and updated edition, provides an in-depth exploration of magnetic resonance theory, including topics such as resonance theory, spin-lattice relaxation, magnetic dipolar broadening, and double resonance. The book is part of the Springer Series in Solid-State Sciences, edited by M. Cardona, P. Fulde, K. von Klitzing, and H.-J. Queisser. It covers a wide range of topics in magnetic resonance, including spin temperature, spin-echo techniques, coherence transfer, multiple quantum coherence, and electron spin resonance. The book also discusses advanced concepts in pulsed magnetic resonance, such as spin-flip narrowing, magic angle spinning, and magnetic resonance imaging. It includes detailed explanations of the density matrix, Bloch equations, and the effects of spin-lattice relaxation. The book is intended as an introductory text for students and researchers in the field of magnetic resonance, providing a rigorous yet accessible treatment of the subject. The content is organized into chapters covering various aspects of magnetic resonance, with a focus on both theoretical and experimental aspects. The book also includes a comprehensive set of problems, appendices, and a detailed bibliography.Conversion of Gaussian to SI Units: To obtain values in SI units, multiply the value in Gaussian units by the respective ratio. The book "Principles of Magnetic Resonance" by Charles P. Slichter, third enlarged and updated edition, provides an in-depth exploration of magnetic resonance theory, including topics such as resonance theory, spin-lattice relaxation, magnetic dipolar broadening, and double resonance. The book is part of the Springer Series in Solid-State Sciences, edited by M. Cardona, P. Fulde, K. von Klitzing, and H.-J. Queisser. It covers a wide range of topics in magnetic resonance, including spin temperature, spin-echo techniques, coherence transfer, multiple quantum coherence, and electron spin resonance. The book also discusses advanced concepts in pulsed magnetic resonance, such as spin-flip narrowing, magic angle spinning, and magnetic resonance imaging. It includes detailed explanations of the density matrix, Bloch equations, and the effects of spin-lattice relaxation. The book is intended as an introductory text for students and researchers in the field of magnetic resonance, providing a rigorous yet accessible treatment of the subject. The content is organized into chapters covering various aspects of magnetic resonance, with a focus on both theoretical and experimental aspects. The book also includes a comprehensive set of problems, appendices, and a detailed bibliography.