Anomalous Effects in Simple Metals / Edition 1

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Overview

Using potassium as an example, this work presents a unique approach to the anomalous effects in metals, resulting in knowledge that can be applied to similar materials.

Most theoretical predictions on the electric, magnetic, optical, and thermal properties of a simple metal do, surprisingly, not agree with experimental behavior found in alkali metals. The purpose of this volume is to document the many phenomena that have violated expectations. The book collects in one place the research by Albert Overhauser, one of the pioneers of the field. His and his collaborators work has led to a unified synthesis of alkali metal peculiarities. The unique collection of 65 reprint papers, commented where necessary to explain the context and perspective, is preceded by a thorough and well paced introduction.

Meant to advanced solid state physics and science historians, this book might also serve as additional reading in advanced solid state physics courses.

Includes a foreword by Mildred and Gene Dresselhaus.

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Editorial Reviews

From the Publisher
"Using potassium as an example, this work presents a unique approach to the anomalous effects in metals, resulting in knowledge that can be applied to similar materials." (ETDE Energy database, 14 February 2011)
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Product Details

  • ISBN-13: 9783527408597
  • Publisher: Wiley, John & Sons, Incorporated
  • Publication date: 12/28/2010
  • Edition description: Reprint
  • Edition number: 1
  • Pages: 706
  • Product dimensions: 6.90 (w) x 9.70 (h) x 1.50 (d)

Meet the Author

Albert Overhauser graduated in Physics and Mathematics at the University of California, Berkeley. In 1951 he was awarded the Ph.D. in Physics for research carried out under the supervision of Charles Kittel. He began his professional career at the University of Illinois where he developed his famous theory of dynamic nuclear polarization which shortly after its experimental confirmation became known by its current name, the Overhauser effect. In 1953 he went to Cornell, which he left in 1958 to accept a position at Ford. In 1973 he became Professor of Physics at Purdue University.

Albert Overhauser has received numerous distiguished honors, and in 1994 was being awarded the National Medal of Science; the highest honor the United States bestows on its citizens for scientific achievement, "For his fundamental contributions to understanding the physics of solids, to theoretical physics and for the impact of his technological advances..."

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Table of Contents

Part I Introduction and Overview

Part II Reprints of SDW or CDW Phenomena in Simple Metals

R1 Giant Spin Density Waves

R2 Mechanism of Antiferromagnetism in Dilute Alloys

R3 Spin Density Waves in an Electron Gas

R4 Spin- Density- Wave Antiferromagnetism in Potassium

R5 Helicon Propagation in Metals Near the Cyclotron Edge

R6 Exchange and Correlation Instabilities of Simple Metals

R7 Splitting of Conduction- Electron Spin Resonance in Potassium

R8 Magnetoresistance of Potassium

R9 Exchange Potentials in a Nonuniform Electron Gas

R10 Observability of Charge- Density Waves by Neutron Diffraction

R11 Questions About the Mayer- El Naby Optical Anomaly in Potassium

R12 Theory of the Residual Resistivity Anomaly in Potassium

R13 Electromagnetic Generation of Ultrasound in Metals

R14 Dynamics of an Incommensurate Charge- Density Wave

R15 Magnetodynamics of Incommensurate Charge- Density Waves

R16 Phase Excitations of Charge Sensity Waves

R17 Frictional Force on a Drifting Charge- Density Wave

R18 Attenuation of Phase Excitations in Charge- Density Wave Systems

R19 Charge- Density Waves and Isotropic Metals

R20 Residual- Resistivity Anisotropy in Potassium

R21 Detection of a Charge- Density Wave by Angle- Resolved Photoemission

R22 Ultra- low- temperature Anomalies in Heat Capacities of Metals Caused by Charge- density Waves

R23 Analysis of the Anomalous Temperature- dependent Resistivity on Potassium Below 1.6 K

R24 Wave- Vector Orientation of a Charge- Density Wave in Potassium

R25 Theory of Transversce Phasons in Potassium

R26 Charge- Density- Wave Satellite Intensity in Potassium

R27 Theory of Electron- Phason Scattering and the Low- temperature Resistivity of Potassium

R28 Structure Factor of a Charge- Density Wave

R29 Effective- Medium Theory of Open- Orbit Inclusions

R30 Theory of the Open- Orbit Magnetoresistance of Potassium

R31 Open- Orbit Magnetoresistance Spectra of Potassium

R32 The Open Orbits of Potassium

R33 Open- Orbits Effects in Thermal Magnetoresistance

R34 Insights in Many- Electron Theory From the Charge Density Wave Structure of Potassium

R35 Charge Density Wave Phenomena in Potassium

R36 Energy Spectrum of an Incommensurate Charge- Density Wave: Potassium and Sodium

R37 Theory of Charge- Density- Wave- Spin- Density- Wave Mixing

R38 Crystal Structure of Lithium at 4.2 K

R39 Theory of Induced- Torque Anomalies in Potassium

R40 Further Evidence of an Anisotropic Hall Coefficient in Potassium

R41 Field Dependence of the Residual- Resistivity Anisotropy in Sodium and Potassium

R42 Effect of an Inhomogeneuous Resistivity on the Induced- Torque Pattern of a Metal Sphere

R43 Infrared- absorption Spectrum of an Incommensurate Charge- Density Wave: Pottassium and Sodium

R44 Dynamic M-shell Effects in the Ultraviolet Absorption Spectrum of Metallic Potasium

R45 Broken Symmentry in Simple Metals

R46 Photoemission from the Charge- Density Wave in Na and K

R47 Phason Narrowing of the Nuclear Magnetic Resonance in Pottassium

R48 Theory of the Perpendicular- Field Cyclotron- Resonance Anomaly in Potassium

R49 Direct Observation of the Charge-Density Wave in Potassium by Neutron Diffraction

R50 Phason Anisotropy and the Nuclear Magnetic Resonance in Potassium

R51 Satellite-Intensity Patterns From the Charge-Density Wave in Potassium

R52 Magnetoserpentine Effect in Single-Crystal Potassium

R53 Charge Density Wave Satellites in Potassium?

R54 Fermi-Surface Structure of Potassium in the Charge-Density-Wave State

R55 Neutron-Diffraction Structure in Potassium Near the [011] and [022] Bragg Points

R56 Quantum Oscillations From the Cylindrical Fermi-Surface Sheet of Potassium Created by the Charge-Density Wave

R57 Magnetotransmission of Microwaves Through Potassium Slabs

R58 Microwave Surface Resistance of Potassium in a Perpendicular Magnetic Field: Effects of the Charge-Density Wave

R59 Cyclotron-Resonance Transmission Through Potassium in a Perpendicular Magnetic Field: Effects of the Charge-Density Wave

R60 Influence of Electron-Electron Scattering on the Electrical Resistivity Caused by Oriented Line Imperfections

R61 Theory of the Fourfold Induced-Torque Anisotropy in Potassium

R62 Observation of Phasons in Metallic Rubidium

R63 Theory of Induced-Torque Anomalies in Potassium

R64 Magnetoflicker Noise in Na and K

R65 Influence of Charge-Density-Wave Structure on Paramagnetic Spin Waves in Alkali Metals

Part III Unexpected Phenomena Exhibited by Metallic Potassium

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