Verfügbarkeit: Anomalous effects in simple metals

Anomalous effects in simple metals:

Gespeichert in:

Bibliographische Detailangaben
1. Verfasser:	Overhauser, Albert Warner 1925- (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Weinheim Wiley-VCH-Verl. 2011
Schlagworte:	Alkalimetall Metallphysik Aufsatzsammlung
Online-Zugang:	Inhaltstext Inhaltsverzeichnis
Beschreibung:	Literaturangaben
Beschreibung:	XVII, 687 S. Ill., graph. Darst. 25 cm
ISBN:	9783527408597

Internformat

MARC


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Datensatz im Suchindex

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adam_text	IMAGE 1 VII CONTENTS FOREWORD V PART I INTRODUCTION AND OVERVIEW ? 1 THE SIMPLEST METAL: POTASSIUM 3 2 SDW AND CDW INSTABILITIES 5 3 THE CDW WAVEVECTOR Q AND Q-DOMAINS 7 4 OPTICAL ANOMALIES 8 5 PHASE EXCITATIONS OF AN INCOMMENSURATE CDW 10 6 NEUTRON DIFFRACTION SATELLITES 12 7 PHASON PHENOMENA 14 8 FERMI-SURFACE DISTORTION AND THE SPIN-RESONANCE SPLITTING 16 9 MAGNETORESISTIVITY AND THE INDUCED TORQUE TECHNIQUE 18 10 INDUCED TORQUE ANISOTROPY 20 11 MICROWAVE TRANSMISSION THROUGH K SLABS IN A PERPENDICULAR FIELD H 22 12 ANGLE-RESOLVED PHOTOEMISSION 24 13 CONCLUDING REMARKS 26 PART II REPRINTS OF SDW OR CDW PHENOMENA IN SIMPLE METALS 29 R 1 GIANT SPIN DENSITY WAVES 33 R 2 MECHANISM OF ANTIFERROMAGNETISM IN DILUTE ALLOYS 38 2.1 INTRODUCTION 38 2.2 DYNAMICS OF A SPIN-DENSITY WAVE 4I 2.3 THERMODYNAMICS OF THE ANTIFERROMAGNETIC PHASE 45 2.4 CONCLUDING REMARKS 47 A APPENDIX 48 A.1 OBJECTION 1 48 A.2 REPLY TO OBJECTION 1 48 BIBLIOGRAFISCHE INFORMATIONEN HTTP://D-NB.INFO/1000249948 DIGITALISIERT DURCH IMAGE 2 VILI I CONTENTS A.3 OBJECTION 2 49 A.4 REPLY TO OBJECTION 2 49 A.5 OBJECTION 3 49 A.6 REPLY TO OBJECTION 3 49 A.7 OBJECTION 4 50 A.8 REPLY TO OBJECTION 4 50 R 3 SPIN DENSITY WAVES IN AN ELECTRON GAS 51 3.1 INTRODUCTION 57 3.2 NATURE OF A SPIN DENSITY WAVE 53 3.3 GENERAL PROOF OF THE SDW INSTABILITY 56 3.4 LINEAR SPIN DENSITY WAVES 60 3.5 SPIN SUSCEPTIBILITY OF THE PARAMAGNETIC STATE 62 3.6 DETECTION OF SDW'S BY NEUTRON DIFFRACTION 65 3.7 TEMPERATURE DEPENDENCE OF SDW PARAMETERS 67 3.8 ANTIFERROMAGNETISM OF CHROMIUM 69 3.9 ACCIDENTAL FERRIMAGNETISM 73 R 4 SPIN-DENSITY-WAVE ANTIFERROMAGNETISM IN POTASSIUM 76 R5 HELICON PROPAGATION IN METALS NEAR THE CYCLOTRON EDGE SO 5.1 INTRODUCTION 80 5.2 THE SURFACE IMPEDANCE 82 5.3 HELICON PROPAGATION IN A SPIN-DENSITY WAVE METAL 87 R 6 EXCHANGE AND CORRELATION INSTABILITIES OF SIMPLE METALS 91 6.1 INTRODUCTION 91 6.2 MATRIX-ELEMENT CONTRIBUTIONS TO THE CORRELATION ENERGY 95 6.3 PARALLEL-SPIN CORRELATION AND UMKLAPP CORRELATION 98 6.4 CHARGE-DENSITY-WAVE INSTABILITIES WO A APPENDIX 102 R 7 SPLITTING OF CONDUCTION-ELECTRON SPIN RESONANCE IN POTASSIUM 105 7.1 INTRODUCTION 105 7.2 ANISOTROPY OF G 107 7.3 STRESS-INDUCED Q DOMAINS 110 R8 MAGNETORESISTANCE OF POTASSIUM 113 8.1 INTRODUCTION 223 8.2 SINGLE-CRYSTAL MAGNETORESISTIVITY OF POTASSIUM II5 8.3 MODEL CALCULATIONS OF MAGNETORESISTANCE IN METALS WITH MAGNETIC BREAKDOWN 125 8.4 FERMI SURFACE OF POTASSIUM 126 8.5 CONCLUSIONS 119 R 9 EXCHANGE POTENTIALS IN A NONUNIFORM ELECTRON GAS 122 R 10 OBSERVABILITY OF CHARGE-DENSITY WAVES BY NEUTRON DIFFRACTION 125 10.1 INTRODUCTION 225 10.2 CDW SATELLITES 226 IMAGE 3 CONTENTS I IX 10.3 STRUCTURE FACTORS OF CUBIC REFLECTIONS 127 10.4 MAGNETIC FIELD MODULATION OF F(K) 128 10.5 PHASE MODULATION OF CDW 129 10.6 DEBYE-WALLER FACTORS FOR PHASONS 132 10.7 SURVEY OF ELECTRONIC ANOMALIES 134 10.7.1 OPTICAL ANOMALIES 134 10.7.2 CONDUCTION-ELECTRON SPIN RESONANCES 234 10.7.3 DOPPLER-SHIFTED CYCLOTRON RESONANCE 235 10.7.4 MAGNETORESISTANCE 235 10.7.5 HALL EFFECT 236 10.7.6 DE HAAS-VAN ALPHEN EFFECT 236 10.7.7 ELECTRON-PHONON INTERACTION 137 10.7.8 POSITRON ANNIHILATION 137 10.7.9 OTHER PROPERTIES 137 10.8 CONCLUSION 238 RII QUESTIONS ABOUT THE MAYER-EL NABY OPTICAL ANOMALY IN POTASSIUM 141 11.1 INTRODUCTION 141 11.2 EXTRINSIC MECHANISMS 142 11.2.1 ABSORPTION IN KOH 142 11.2.2 INTERFERENCE 142 11.2.3 SURFACE ROUGHNESS 243 11.2.4 PLASMON ABSORPTION 243 11.2.5 SCATTERING BY KOH AGGREGATES 243 11.2.6 COLOR CENTERS IN KOH 243 11.2.7 SURFACE STATES 244 11.2.8 ABSORPTION BY K PARTICLES IN KOH 244 11.2.9 IMPURITY ABSORPTION IN POTASSIUM 144 11.2.10 UNKNOWN MECHANISM 244 11.3 INTRINSIC MECHANISMS 145 11.4 TWO CRITICAL EXPERIMENTS 147 R 12 THEORY OF THE RESIDUAL RESISTIVITY ANOMALY IN POTASSIUM 149 R 13 ELECTROMAGNETIC GENERATION OF ULTRASOUND IN METALS 154 13.1 INTRODUCTION 154 13.2 FORCE ON LATTICE IONS 157 13.3 GENERATED SOUND-WAVE AMPLITUDE 158 13.3.1 LOCAL LIMIT 260 13.3.2 NONLOCAL LIMIT 262 13.4 ULTRASONIC ATTENUATION AND THE HELICON-PHONON INTERACTION 263 13.4.1 ULTRASONIC ATTENUATION 263 13.4.2 HELICON-PHONON INTERACTION 265 13.5 SUMMARY AND CONCLUDING REMARKS 166 A APPENDIX 166 IMAGE 4 X I CONTENTS R 14 DYNAMICS OF AN INCOMMENSURATE CHARGE-DENSITY WAVE 169 14.1 INTRODUCTION 269 14.2 EQUATIONS OF MOTION 170 14.3 JELLIUM MODEL FOR A CDW 171 14.4 CURRENT 172 14.5 EFFECTS OF AN APPLIED ELECTRIC FIELD 173 14.6 CDW ACCELERATION AND EFFECTIVE MASS 175 14.7 CONCLUSION 177 A APPENDIX 777 R15 MAGNETODYNAMICS OF INCOMMENSURATE CHARGE-DENSITY WAVES 179 15.1 INTRODUCTION 179 15.2 EQUATIONS OF MOTION 179 15.3 EFFECTS OF AN APPLIED MAGNETIC FIELD 180 15.4 MAGNETORESISTANCE AND HALL COEFFICIENT 185 15.5 THEORY OF THE INDUCED TORQUE 286 15.6 CONCLUSIONS 187 A APPENDIX 188 R16 PHASE EXCITATIONS OF CHARGE DENSITY WAVES 190 16.1 FERMI-SURFACE INSTABILITIES 190 16.2 HYPERFINE EFFECTS OF CDW'S 192 16.3 PHASONS 192 16.4 PHASON TEMPERATURE FACTOR 293 16.5 PHASON NARROWING OF HYPERFINE BROADENING 194 16.6 CONCLUSIONS 796 A DISCUSSION 196 R 17 FRICTIONAL FORCE ON A DRIFTING CHARGE-DENSITY WAVE 199 17.1 INTRODUCTION 199 17.2 EQUILIBRIUM ELECTRON DISTRIBUTION 200 17.3 ELECTRON RELAXATION TIME 205 17.4 FRICTIONAL EFFECTS OF SCATTERING ON THE CDW DRIFT VELOCITY 207 17.5 CONCLUSIONS 220 R 18 ATTENUATION OF PHASE EXCITATIONS IN CHARGE-DENSITY WAVE SYSTEMS 212 18.1 INTRODUCTION 212 18.2 PHASONS AND ELECTRON-PHASON INTERACTION 213 18.3 SCATTERING OF "BELLY" ELECTRONS 215 18.4 SCATTERING OF "CONICAL POINT" ELECTRONS 217 18.5 CONCLUSIONS 219 A APPENDIX 220 R19 CHARGE-DENSITY WAVES AND ISOTROPIE METALS 221 19.1 INTRODUCTION 227 19.2 THEORETICAL SUMMARY 222 19.2.1 WAVE-MECHANICAL DESCRIPTION 222 IMAGE 5 CONTENTS I XI 19.2.2 DETECTION OFCDWS BY DIFFRACTION 224 19.2.3 FERMI-SURFACE INSTABILITY THEOREM 225 19.2.4 ROLE OF ELECTRON CORRELATIONS 225 19.2.5 FERMI-SURFACE SHAPE AND DIMENSIONALTY 226 19.2.6 CDW INSTABILITY IN ISOTROPIE METALS 228 19.3 EXPERIMENTAL MANIFESTATIONS 229 19.3.1 THE ALKALI METALS 229 19.3.2 TORQUE ANOMALIES 230 19.3.3 OPTICAL ANOMALIES 231 19.3.4 SPIN-RESONANCE ANISOTROPY 232 19.3.5 RESIDUAL-RESISTIVITY ANISOTROPY 232 19.3.6 HALL COEFFICIENT DISCREPANCY 232 19.3.7 THE SIGNIFICANCE OF IRREPRODUCIBILITY 233 19.3.8 THE CHALLENGE: Q DOMAIN CONTROL 233 19.3.9 PHASE EXCITATIONS AND SATELLITE INTENSITY 234 19.3.10 THE DE HAAS-VAN ALPHEN DIFFICULTY 235 19.4 PROSPECTS FOR THE FUTURE 235 R 20 RESIDUAL-RESISTIVITY ANISOTROPY IN POTASSIUM 238 20.1 INTRODUCTION 238 20.2 INDUCED-TORQUE EXPERIMENTS 239 20.3 CHARGE-DENSITY WAVES 243 20.4 MODEL SCATTERING POTENTIALS 247 20.5 RESIDUAL-RESTIVITY CALCULATION 250 20.6 NUMERICAL RESULTS 256 20.7 CONCLUSIONS 260 R 21 DETECTION OF A CHARGE-DENSITY WAVE BY ANGLE-RESOLVED PHOTOEMISSION 262 R 22 ULTRA-LOW-TEMPERATURE ANOMALIES IN HEAT CAPACITIES OF METALS CAUSED BY CHARGE-DENSITY WAVES 266 22.1 INTRODUCTION 266 22.2 PHASON HEAT CAPACITY 267 22.3 TOTAL HEAT CAPACITY 269 22.4 CONCLUSION 273 R23 ANALYSIS OF THE ANOMALOUS TEMPERATURE-DEPENDENT RESISTIVITY ON POTASSIUM BELOW 1.6 K 274 R 24 WAVE-VECTOR ORIENTATION OF A CHARGE-DENSITY WAVE IN POTASSIUM 278 24.1 INTRODUCTION 278 24.2 SOURCES OF ANISOTROPY 278 24.3 GEOMETRICAL FACTORS 279 24.4 ENERGY ANALYSIS 280 24.5 RESULTS 281 R 25 THEORY OF TRANSVERSE PHASONS IN POTASSIUM 284 25.1 INTRODUCTION 284 IMAGE 6 XII I CONTENTS 25.2 PHASON ENERGY SPECTRUM 284 25.3 ENERGY OF THE CONDUCTION ELECTRON-ION SYSTEM 287 25.4 TRANSVERSE-PHASON VELOCITY IN POTASSIUM 290 25.5 DISCUSSION 291 A POSITIVE-ION FORM FACTORS 292 A.I PSEUDO-ION FORM FACTOR P- 292 A.2 REAL-ION FORM FACTOR P^ 293 B CDW ENERGY MINIMIZATION 293 R26 CHARGE-DENSITY-WAVE SATELLITE INTENSITY IN POTASSIUM 295 26.1 INTRODUCTION 295 26.2 NEUTRON-SCATTERING ELASTIC INTENSITY 296 26.3 LATTICE DISTORTION 298 26.4 CDW FRACTIONAL AMPLITUDE IN POTASSIUM 298 26.5 RESULTS 300 R 27 THEORY OF ELECTRON-PHASON SCATTERING AND THE LOW-TEMPERATURE RESISTIVITY OF POTASSIUM 302 27.1 INTRODUCTION 302 27.2 ANALYSIS OF EXPERIMENTS 303 27.3 PHASONS AND THE ELECTRON-PHASON INTERACTION 307 27.4 DERIVATION OF THE ELECTRON-PHASON RESISTIVITY 373 27.5 NUMERICAL RESULTS 321 27.6 CONCLUSIONS 324 R 28 STRUCTURE FACTOR OF A CHARGE-DENSITY WAVE 327 28.1 INTRODUCTION 327 28.2 DYNAMICAL STRUCTURE FACTOR FOR A CDW 328 28.3 EXCITATION SPECTRUM 332 28.4 PHASON AND AMPLITON TEMPERATURE FACTORS 333 28.5 DISCUSSION 335 R 29 EFFECTIVE-MEDIUM THEORY OF OPEN-ORBIT INCLUSIONS 338 29.1 INTRODUCTION 338 29.2 APPROXIMATIONS FOR THE EFFECTIVE CONDUCTIVITY 338 29.3 ELECTRIC FIELD IN A SPHERICAL INHOMOGENEITY 340 29.4 MAGNETORESISTANCE OF OPEN-ORBIT INCLUSIONS 342 29.5 DISCUSSION 346 R 30 THEORY OF THE OPEN-ORBIT MAGNETORESISTANCE OF POTASSIUM 348 R31 OPEN-ORBIT MAGNETORESISTANCE SPECTRA OF POTASSIUM 353 31.1 INTRODUCTION 353 31.2 OPEN-ORBIT MAGNETORESISTANCE 355 31.3 OPEN-ORBIT DIRECTIONS 357 31.4 OPEN-ORBIT MAGNETORESISTANCE OF POTASSIUM 359 31.5 DIRECTIONS FOR FUTURE RESEARCH 363 31.6 CONCLUSION 364 IMAGE 7 CONTENTS I XIII R32 THE OPEN ORBITS OF POTASSIUM 369 32.1 INTRODUCTION 369 32.2 DIRECT OBSERVATION OF OPEN ORBITS 370 32.3 OPEN ORBITSOFA SINGLE Q DOMAIN 371 32.4 EFFECTIVE-MEDIUM THEORY FOR Q DOMAINS 373 32.5 DISCUSSION 375 R 33 OPEN-ORBIT EFFECTS IN THERMAL MAGNETORESISTANCE 377 33.1 INTRODUCTION 377 33.2 THEORY 377 33.3 RESULTS 379 33.4 DISCUSSION 381 R 34 INSIGHTS IN MANY-ELECTRON THEORY FROM THE CHARGE DENSITY WAVE STRUCTURE OF POTASSIUM 383 34.1 INTRODUCTION 383 34.2 OPTICAL ABSORPTION OF A CDW 384 34.3 OTHER CDW PHENOMENA IN K 386 34.3.1 CONDUCTION-ELECTRON SPIN-RESONANCE SPLITTING 386 34.3.2 DOPPLER-SHIFTED CYCLOTRON-RESONANCE SHIFT 386 34.3.3 RESIDUAL RESISTIVITY ANISOTROPY 386 34.3.4 LINEAR MAGNETORESISTANCE 387 34.3.5 INDUCED TORQUE ANISOTROPY 387 34.3.6 THE OU DROP EFFECT 387 34.3.7 VARIABILITY OF THE RESIDUAL RESISTIVITY 387 34.3.8 HIGH-FIELD HALL CONSTANT 387 34.3.9 PHASON HEAT CAPACITY ANOMALY 388 34.3.10 DIRECT OBSERVATION OF ELECTRON-PHASON SCATTERING 388 34.3.11 DIFFICULTIES 388 34.4 THE OPEN ORBITS OF POTASSIUM 388 34.4.1 ORIGIN OF OPEN ORBITS 388 34.4.2 THEORETICAL OPEN-ORBIT SPECTRUM 389 34.4.3 OBSERVED OPEN-ORBIT SPECTRUM 390 34.5 IMPLICATIONS FOR MANY-ELECTRON THEORY 390 34.5.1 LOCAL-DENSITY APPROXIMATIONS TO EXCHANGE AND CORRELATION ARE NOT PREDICTIVE 390 34.5.2 SCREENED INTERACTIONS ARE DANGEROUS 392 34.5.3 THE COULOMB HOLE IS IMPORTANT 392 R 35 CHARGE DENSITY WAVE PHENOMENA IN POTASSIUM 394 35.1 THE MYSTERIES OF THE SIMPLE METALS 394 35.1.1 INTRODUCTION 394 35.1.2 CHARGE-DENSITY-WAVE STRUCTURE 394 35.1.3 MAYER-EL NABY OPTICAL ANOMALY 395 35.1.4 LOW-TEMPERATURE MAGNETORESISTANCE 396 35.1.5 INDUCED-TORQUE MEASUREMENTS 397 35.1.6 THE OIL DROP EFFECT 398 35.1.7 OTHER ANOMALOUS PHENOMENA 398 IMAGE 8 XIV I CONTENTS 35.2 PHASONS: WHAT THEY ARE AND WHAT THEY DO 399 35.2.1 INTRODUCTION 399 35.2.2 PHASE MODULATION 399 35.2.3 RELATION BETWEEN PHASONS AND PHONONS 400 35.2.4 THE PHASON HEAT CAPACITY 407 35.2.5 LOW TEMPERATURE RESISTIVITY 402 35.2.6 POINT CONTACT SPECTROSCOPY 403 35.2.7 PHASON THERMAL DIFFUSE SCATTERING 403 35.3 THEORY OF CHARGE DENSITY WAVES 404 35.3.1 INTRODUCTION 404 35.3.2 SDW-CDW INSTABILITY THEOREM 404 35.3.3 THE CORRELATION ENERGY CORRECTION 405 35.3.4 ANALOGY WITH UNIFORM DEFORMATIONS 407 35.4 CONCLUSIONS 408 R 36 ENERGY SPECTRUM OF AN INCOMMENSURATE CHARGE-DENSITY WAVE: POTASSIUM AND SODIUM 411 36.1 INTRODUCTION 411 36.2 MINIGAPS AND HETERODYNE GAPS 412 36.3 RESULTS FOR NA AND K 416 36.4 CONCLUSIONS 418 R 37 THEORY OF CHARGE-DENSITY-WAVE-SPIN-DENSITY-WAVE MIXING 420 R 38 CRYSTAL STRUCTURE OF LITHIUM AT 4.2 K 424 R 39 THEORY OF INDUCED-TORQUE ANOMALIES IN POTASSIUM 427 39.1 INTRODUCTION 427 39.2 INDUCED-TORQUE ANOMALIES 428 39.3 MAGNETORESISTIVITY TENSOR OF POTASSIUM 430 39.4 CALCULATION OF INDUCED TORQUE 432 39.5 DISCUSSION 435 R 40 FURTHER EVIDENCE OF AN ANISOTROPIE HALL COEFFICIENT IN POTASSIUM 436 40.1 INTRODUCTION 436 40.2 MISALIGNMENT EFFECT 438 40.3 PHASE ANOMALIES 439 40.4 DISCUSSION 444 R 41 FIELD DEPENDENCE OF THE RESIDUAL-RESISTIVITY ANISOTROPY IN SODIUM AND POTASSIUM 446 41.1 INTRODUCTION 446 41.2 ANISOTROPIE RELAXATION TIME 447 41.3 ZERO-FIELD RESISTANCE 448 41.4 MAGNETORESISTANCE 450 41.5 INDUCED TORQUE 454 41.6 DISCUSSION 456 A APPENDIX 457 IMAGE 9 CONTENTS I XV R 42 EFFECT OF AN INHOMOGENEOUS RESISTIVITY ON THE INDUCED-TORQUE PATTERN OF A METAL SPHERE 460 R 43 INFRARED-ABSORPTION SPECTRUM OF AN INCOMMENSURATE CHARGE-DENSITY WAVE: POTASSIUM AND SODIUM 465 43.1 INTRODUCTION 465 43.2 MINIGAP ABSORPTION 468 43.3 RESULTS FOR K AND NA 471 43.4 CONCLUSIONS 474 R 44 DYNAMIC M-SHELL EFFECTS IN THE ULTRAVIOLET ABSORPTION SPECTRUM OF METALLIC POTASSIUM 476 R45 BROKEN SYMMETRY IN SIMPLE METALS 482 45.1 INTRODUCTION 481 45.2 THE EVIDENCE 482 45.3 THEORY OF CHARGE DENSITY WAVES 486 45.3.1 SDW-CDW INSTABILITY THEOREM 486 45.3.2 THE CORRELATION ENERGY CORRECTION 488 45.3.3 ANALOGY WITH UNIFORM DEFORMATIONS 490 45.3.4 IMPLICATIONS FOR MANY-ELECTRON THEORY 490 45.4 CDW PHENOMENA 493 45.4.1 OPTICAL ANOMALIES 493 45.4.2 CONDUCTION ELECTRON SPIN RESONANCE SPLITTING 494 45.4.3 NONREPRODUCIBILITY, A CONSEQUENCE OF Q DOMAINS 494 45.4.4 LINEAR MAGNETORESISTANCE 495 45.4.5 HALL COEFFICIENT DISCREPANCY 495 45.4.6 INDUCED-TORQUE ANISOTROPY 495 45.4.7 THE OIL DROP EFFECT 497 45.4.8 RESIDUAL-RESISTANCE ANISOTROPY 497 45.4.9 TEMPERATURE DEPENDENCE OF RESISTIVITY NEAR 1 K 498 45.4.10 TEMPERATURE DEPENDENCE OF THE SURFACE IMPEDANCE 499 45.4.11 DEVIATIONS FROM MATTHIESSEN'S RULE 499 45.4.12 DOPPLER-SHIFTED CYCLOTRON RESONANCE 499 45.4.13 PHASON ANOMALY IN POINT CONTACT SPECTROSCOPY 500 45.5 CONCLUSION 501 R 46 PHOTOEMISSION FROM THE CHARGE-DENSITY WAVE IN NA AND K 505 R47 PHASON NARROWING OF THE NUCLEAR MAGNETIC RESONANCE IN POTASSIUM 509 47.1 INTRODUCTION 509 47.2 NMR LINE SHAPE AT T = OK 510 47.3 REVIEW OF PHASON PROPERTIES 512 47.4 MOTIONAL NARROWING BY PHASONS 513 47.5 TEMPERATURE DEPENDENCE OF AH 515 IMAGE 10 XVII CONTENTS R48 THEORY OF THE PERPENDICULAR-FIELD CYCLOTRON-RESONANCE ANOMALY IN POTASSIUM 517 48.1 INTRODUCTION 517 48.2 CHARGE-DENSITY-WAVE STRUCTURE AND THE FERMI SURFACE 518 48.3 THEORY OF THE SURFACE IMPEDANCE 520 48.4 RESULTS AND DISCUSSION 522 48.5 CONCLUSIONS 524 R 49 DIRECT OBSERVATION OF THE CHARGE-DENSITY WAVE IN POTASSIUM BY NEUTRON DIFFRACTION 526 R 50 PHASON ANISOTROPY AND THE NUCLEAR MAGNETIC RESONANCE IN POTASSIUM 532 R 51 SATELLITE-INTENSITY PATTERNS FROM THE CHARGE-DENSITY WAVE IN POTASSIUM 537 R 52 MAGNETOSERPENTINE EFFECT N SINGLE-CRYSTAL POTASSIUM 541 R 53 CHARGE DENSITY WAVE SATELLITES IN POTASSIUM? 545 R 54 FERMI-SURFACE STRUCTURE OF POTASSIUM IN THE CHARGE-DENSITY-WAVE STATE 557 54.1 INTRODUCTION 557 54.2 PLANE-WAVE EXPANSION 558 54.3 APPROXIMATE SOLUTIONS 559 54.3.1 NEAR K * Q SI Q/2 (MINIGAP REGION) 559 54.3.2 NEAR K ' Q' = Q' (HETERODYNE-GAP REGION) 561 54.4 CONCLUSIONS 563 R 55 NEUTRON-DIFFRACTION STRUCTURE IN POTASSIUM NEAR THE [011] AND [022] BRAGG POINTS 565 R 56 QUANTUM OSCILLATIONS FROM THE CYLINDRICAL FERMI-SURFACE SHEET OF POTASSIUM CREATED BY THE CHARGE-DENSITY WAVE 571 R 57 MAGNETOTRANSMISSION OF MICROWAVES THROUGH POTASSIUM SLABS 578 57.1 INTRODUCTION 578 57.2 NONLOCAL THEORY FOR AN ISOTROPIE FERMI SURFACE 581 57.3 SUPPRESSION OFGK OSCILLATIONS BY A CHARGE-DENSITY WAVE 584 57.4 CONCLUSION 586 R 58 MICROWAVE SURFACE RESISTANCE OF POTASSIUM IN A PERPENDICULAR MAGNETIC FIELD: EFFECTS OF THE CHARGE-DENSITY WAVE 589 58.1 INTRODUCTION 589 58.2 EFFECT OF THE HETERODYNE GAPS 591 58.3 RESONANCE FROM THE FERMI-SURFACE CYLINDER 595 58.4 CONCLUSION 601 A CALCULATION OF THE CONDUCTIVITY 603 B POLARIZATION OF THE FIELD INSIDE AN ANISOTROPIE METAL 605 IMAGE 11 CONTENTS I XVII R 59 CYCLOTRON-RESONANCE TRANSMISSION THROUGH POTASSIUM IN A PERPENDICULAR MAGNETIC FIELD: EFFECTS OF THE CHARGE-DENSITY WAVE 610 59.1 INTRODUCTION 620 59.2 MICROWAVE TRANSMISSION IN AN ANISOTROPIE, NONLOCAL MEDIUM 614 59.3 EFFECT OF MINIGAPS ON MICROWAVE TRANSMISSION 617 59.4 CONDUCTIVITY TENSOR FROM A TILTED FERMI-SURFACE CYLINDER 621 59.5 CONCLUSIONS 625 R 60 INFLUENCE OF ELECTRON-ELECTRON SCATTERING ON THE ELECTRICAL RESISTIVITY CAUSED BY ORIENTED LINE IMPERFECTIONS 627 60.1 INTRODUCTION 627 60.2 THEORY 627 60.3 DISCUSSION 631 R 61 THEORY OF THE FOURFOLD INDUCED-TORQUE ANISOTROPY IN POTASSIUM 633 R 62 OBSERVATION OF PHASONS IN METALLIC RUBIDIUM 642 R 63 THEORY OF INDUCED-TORQUE ANOMALIES IN POTASSIUM 646 R 64 MAGNETOFLICKER NOISE IN NA AND K 651 64.1 BACKGROUND 651 64.2 CDW STRUCTURE 652 64.3 FLUCTUATIONS OF Q AND Q' 653 64.4 MAGNETORESISTANCE OF A THIN WIRE 656 64.5 MAGNETOPHASON NOISE 657 64.6 CONCLUSION 659 R 65 INFLUENCE OF CHARGE-DENSITY-WAVE STRUCTURE ON PARAMAGNETIC SPIN WAVES IN ALKALI METALS 662 65.1 INTRODUCTION 662 65.2 BRIEF REVIEW OF CHARGE-DENSITY-WAVE THEORY 663 65.3 BRIEF REVIEW OF LANDAU FERMI-LIQUID THEORY 666 65.4 SIMPLIFIED MODEL FOR CHARGE-DENSITY-WAVE EFFECTS 670 65.4.1 CLOSED ORBITS 671 65.4.2 OPEN ORBITS 675 65.4.3 MIXED ORBITS 676 65.4.4 TRANSMITTED SIGNALS 677 65.5 COMPARISON WITH THE PLATZMAN-WOLFF THEORY AND EXPERIMENTAL DATA 678 65.6 CONCLUSION 682 PARTILI THIRTY UNEXPECTED PHENOMENA EXHIBITED BY METALLIC POTASSIUM 685
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discipline	Physik Werkstoffwissenschaften / Fertigungstechnik
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indexdate	2024-07-20T10:59:23Z
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isbn	9783527408597
language	English
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publisher	Wiley-VCH-Verl.
record_format	marc
spelling	Overhauser, Albert Warner 1925- Verfasser (DE-588)142721484 aut Anomalous effects in simple metals Albert Overhauser Weinheim Wiley-VCH-Verl. 2011 XVII, 687 S. Ill., graph. Darst. 25 cm txt rdacontent n rdamedia nc rdacarrier Literaturangaben Alkalimetall (DE-588)4224517-5 gnd rswk-swf Metallphysik (DE-588)4169621-9 gnd rswk-swf (DE-588)4143413-4 Aufsatzsammlung gnd-content Alkalimetall (DE-588)4224517-5 s Metallphysik (DE-588)4169621-9 s DE-604 X:MVB text/html http://deposit.dnb.de/cgi-bin/dokserv?id=3428181&prov=M&dok_var=1&dok_ext=htm Inhaltstext DNB Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=021152104&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Overhauser, Albert Warner 1925- Anomalous effects in simple metals Alkalimetall (DE-588)4224517-5 gnd Metallphysik (DE-588)4169621-9 gnd
subject_GND	(DE-588)4224517-5 (DE-588)4169621-9 (DE-588)4143413-4
title	Anomalous effects in simple metals
title_auth	Anomalous effects in simple metals
title_exact_search	Anomalous effects in simple metals
title_full	Anomalous effects in simple metals Albert Overhauser
title_fullStr	Anomalous effects in simple metals Albert Overhauser
title_full_unstemmed	Anomalous effects in simple metals Albert Overhauser
title_short	Anomalous effects in simple metals
title_sort	anomalous effects in simple metals
topic	Alkalimetall (DE-588)4224517-5 gnd Metallphysik (DE-588)4169621-9 gnd
topic_facet	Alkalimetall Metallphysik Aufsatzsammlung
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work_keys_str_mv	AT overhauseralbertwarner anomalouseffectsinsimplemetals

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