05404nam 2200709Ia 450 991101999390332120200520144314.0978661237163997812823716371282371630978144431334514443133479781444313338144431333997806320633210632063327(CKB)111056486485714(EBL)454366(OCoLC)741346687(SSID)ssj0000194710(PQKBManifestationID)11166566(PQKBTitleCode)TC0000194710(PQKBWorkID)10231941(PQKB)10035916(MiAaPQ)EBC454366(Perlego)2763508(EXLCZ)9911105648648571419980423d1999 uy 0engur|n|---|||||txtccrLow-grade metamorphism /[edited by] Martin Frey, Doug RobinsonOxford, England ;Malden, Mass. Blackwell Science19991 online resource (325 p.)Description based upon print version of record.9780632047567 0632047569 Includes bibliographical references (p. 261-301) and index.Low-Grade Metamorphism; Contents; List of contributors; Preface; 1: Low-temperature metamorphism: an overview; 1.1 What is it?; 1.2 A decade of progress; 1.3 Very low-grade metamorphism in a global setting; 1.4 Does low-tempereture metamorphism matter?; 1.5 Mineral abbreviations; 2: Very low-grade metapelites: mineralogy, microfabrics and measuring reaction progress; 2.1 Metapelitic rock.; 2.1.1 Introduction; 2.1.2 Metapelitic zones and lithology; 2.1.3 Metastable equilibrium and clay mineral reaction progress; 2.2 Mineralogical relations; 2.2.1 Phyllosilicate reaction series2.2.2 Smectite-I/S-illite-muscovite2.2.3 Smectite-corrensite-chlorite; 2.2.4 Kaolinite-pyrophyllite; 2.2.5 Berthierine; 2.3 Metapelitic microfabrics; 2.3.1 Introduction; 2.3.2 Mlcrofabrics of the late diagenetic zone; 2.3.3 The anchizone and slaty cleavage development; 2.3.4 The anchizone-epizone transition; 2.4 Measuring reaction progress; 2.4.1 X-ray diffraction techniques; 2.4.2 Transmission electron microscope techniques; 2.4.3 Correlation of X·ray diffraction and transmission electron microscope measurements; 2.4.4 Retrogression; 2.5 Geothermometry and geobarometry2.5.1 Illite-smectite reaction2.5.2 Illite and chlorite crystallinity; 2.5.3 Chlorite geothermometers; 2.5.4 Polytypism of chlorite and white mica; 2.5.5 Phengite geobarometer; 2.6 Overview of conditions of very low-grade metamorphism; 2.7 Future research; 3: Patterns of very low-grade metamorphism in metapelitic rocks; 3.1 Introduction; 3.2 Sampling and data interpretation; 3.2.1 Field sampling; 3.2.2 Methods of displaying regional metapelitic data; 3.2.3 Metapelites and basin maturity; 3.2.4 Pattern recognition; 3.3 Regional patterns of very low-grade metamorphism; 3.3.1 Geotectonic setting3.3.2 Extensional settings3.3.3 Accretionary settings; 3.3.4 Collisional settings; 3.3.5 High strain zones; 3.4 Low-temperature contact metamorphism; 3.4.1 Aureoles predating regional metamorphism; 3.4.2 Aureoles postdating regional metamorphism; 3.5 Regional controls on metapelitic patterns; 3.6 Conclusions; 4: Petrological methods for the study of very low-grade metabasites; 4.1 Introduction; 4.2 Field study of very low-grade metabasites; 4.3 Primary features; 4.3.1 Glass and palagonite; 4.3.2 Primary minerals; 4.3.3 Vesicles; 4.4 Secondary minerals; 4.4.1 Mafic layer silicates4.4.2 Pumpellyite, prehnite and epidote4.4.3 Other minerals; 4.5 Electron microprobe analysis of low-grade metabasites; 4.5.1 Analytical conditions; 4.5.2 Analytical difficulties; 4.5.3 Standards; 4.5.4 Analytical uncertainties; 4.5.5 Criteria for a good analysis; 4.6 Quantitative application of electron microprobe data; 4.6.1 Projections or low-grade mineral assemblages; 4.6.2 Projection from chlorite; 4.6.3 Projections from calcium-aluminium silicates; 4.6.4 Algebraic methods; 4.6.5 Petrogenetic grids; 4.6.6 Thermobarometry; 4.7 Summary5: Patterns of regional low-grade metamorphism in metabasitesLow-Grade Metamorphism explores processes and transformations in rocks during the early stages of metamorphic recrystallization. There has been little analysis and documentation of this widespread phenomenon, especially of the substantial and exciting advances that have taken place in the subject over the last decade. This book rectifies that shortfall, building on the foundations of Low-Temperature Metamorphism by Martin Frey (1987). The editors have invited contributions from an internationally acknowledged team of experts, who have aimed the book at advanced undergraduate and Metamorphism (Geology)GeologyMetamorphism (Geology)Geology.552552/.4Frey Martin1940-881265Robinson Doug1947-448148MiAaPQMiAaPQMiAaPQBOOK9911019993903321Low-grade metamorphism1968196UNINA04424nam 2200601Ia 450 991102001100332120200520144314.01-280-72299-197866107229903-527-60995-43-527-60950-4(CKB)1000000000377462(EBL)481571(OCoLC)744977379(SSID)ssj0000250287(PQKBManifestationID)11194180(PQKBTitleCode)TC0000250287(PQKBWorkID)10230933(PQKB)10022416(MiAaPQ)EBC481571(EXLCZ)99100000000037746220030725d2006 uy 0engur|n|---|||||txtccrThe SQUID handbookVolume 2Applications of SQUIDs and SQUID systems /J. Clarke, A.I. Braginski, edsWeinheim Wiley-VCH20061 online resource (654 p.)Description based upon print version of record.3-527-40408-2 Includes bibliographical references and index.The SQUID Handbook Vol. II; Contents; Volume I; Volume II; Preface; List of Contributors; 8 SQUID Voltmeters and Amplifiers; 8.1 Introduction; 8.2 Voltmeters; 8.3 The SQUID as a Radiofrequency Amplifier; 8.4 Microstrip SQUID Amplifier; 8.5 SQUID Readout of Thermal Detectors; 8.6 Nuclear Magnetic and Quadrupole Resonance and Magnetic Resonance Imaging; 8.7 The Axion Detector; 9 SQUIDs for Standards and Metrology; 9.1 Introduction; 9.2 SQUIDs in Voltage Metrology; 9.3 Cryogenic Current Comparator (CCC); 9.4 Other Current Metrological Applications of SQUIDs; 9.5 Future Trends and Conclusion10 The Magnetic Inverse Problem10.1 The Peculiarities of the Magnetic Inverse Problem; 10.2 The Magnetic Forward Problem; 10.3 The Magnetic Inverse Problem; 10.4 Conclusions; 11 Biomagnetism; 11.1 Introduction; 11.2 Magnetoencephalography; 11.3 Magnetocardiography; 11.4 Quasistatic Field Magnetometry; 11.5 Magnetoneurography; 11.6 Liver Susceptometry; 11.7 Gastromagnetometry; 11.8 Magnetic Relaxation Immunoassays; 12 Measurements of Magnetism and Magnetic Properties of Matter; 12.1 Introduction; 12.2 The SQUID Magnetometer-Susceptometer; 12.3 Scanning SQUID Microscopy13 Nondestructive Evaluation of Materials and Structures using SQUIDs13.1 Introduction; 13.2 Detection of Magnetic Moments; 13.3 Magnetic Flux Leakage Technique; 13.4 Static Current Distribution Mapping; 13.5 Eddy Current Technique; 13.6 Alternative Excitation Techniques; 13.7 Conclusion and Prospects; 14 SQUIDs for Geophysical Survey and Magnetic Anomaly Detection; 14.1 Introduction; 14.2 Magnetic Measurements in the Earth's Field; 14.3 Operation of SQUIDs in Real World Environments; 14.4 Data Acquisition and Signal Processing; 14.5 Geophysical Applications of SQUIDs14.6 Magnetic Anomaly Detection Systems using SQUIDs14.7 Future Prospects; 15 Gravity and Motion Sensors; 15.1 Introduction; 15.2 The Superconducting Accelerometer; 15.3 Superconducting Transducer for Gravitational-Wave Detectors; 15.4 Superconducting Gravity Gradiometers (SGGs); 15.5 Applications of the SGG Technology; 15.6 Outlook; Appendix; Physical Constants, Abbreviations, and Symbols; IndexThis two-volume handbook offers a comprehensive and coordinated presentation of SQUIDs (Superconducting Quantum Interference Devices), including device fundamentals, design, technology, system construction and multiple applications. It is intended to bridge the gap between fundamentals and applications, and will be a valuable textbook reference for graduate students and for professionals engaged in SQUID research and engineering. It will also be of use to specialists in multiple fields of practical SQUID applications, from human brain research and heart diagnostics to airplane and nuclear planSuperconducting quantum interference devicesSuperconductivitySuperconducting quantum interference devices.Superconductivity.621.3815681.2Clarke J1837384Braginski A. I902216MiAaPQMiAaPQMiAaPQBOOK9911020011003321The SQUID handbook4416096UNINA