Crustal Magmatic System Evolution Anatomy Architecture and Physico Chemical Processes 1st edition by Matteo Masotta 1119564468 9781119564461

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ISBN-10 :  1119564468 

ISBN-13 :  9781119564461

Author : Matteo Masotta 

A comprehensive picture of the architecture of crustal magmatic systems   The composition of igneous rocks – their minerals, melts, and fluids – reveals the physical and chemical conditions under which magmas form, evolve, interact, and move from the Earth’s mantle through the crust. These magma dynamics affect processes on the surface including crustal growth and eruptive behaviour of volcanoes.  Crustal Magmatic System Evolution: Anatomy, Architecture, and Physico-Chemical Processes uses analytical, experimental, and numerical approaches to explore the diversity of crustal processes from magma differentiation and assimilation to eruption at the surface.  Volume highlights include:  Physical and chemical parameterization of crustal magmatic systems   Experimental, theoretical and modelling approaches targeting crustal magmatic processes  Timescales of crustal magmatic processes, including storage, recharge, and ascent through volcanic conduits   The American Geophysical Union promotes discovery in Earth and space science for the benefit of humanity. Its publications disseminate scientific knowledge and provide resources for researchers, students, and professionals.

Crustal Magmatic System Evolution: Anatomy, Architecture, and Physico-Chemical Processes 1st Table of contents:

Part I: Architecture of Crustal Magmatic Systems
1 Geothermobarometry of Mafic and Ultramafic Xenoliths: Examples From Hualalai and Mauna Kea Volcanoes, Hawaii
1.1. INTRODUCTION
1.2. GEOLOGICAL AND PETROLOGICAL BACKGROUND
1.3. REVISED GEOTHERMOBAROMETRY OF MAUNA KEA AND HUALALAI XENOLITHS
1.4. DISCUSSION
1.5. CONCLUSIONS AND FUTURE PERSPECTIVES
ACKNOWLEDGMENTS
REFERENCES
2 Trace Element Geothermometry and Geospeedometry for Cumulate Rocks: Quantitative Constraints on Thermal and Magmatic Processes During Igneous Crust Formation
2.1. INTRODUCTION
2.2. A TRACE ELEMENT PERSPECTIVE FOR DECODING THERMAL AND MAGMATIC RECORDS IN MINERALS
2.3. TRACE ELEMENT GEOTHERMOMETRY
2.4. TRACE ELEMENT GEOSPEEDOMETRY
2.5. A CASE STUDY ON OCEANIC CRUST FORMATION
2.6. CONCLUDING REMARKS
ACKNOWLEDGMENTS
REFERENCES
3 Magma Storage at Ocean Islands: Insights From Cape Verde
3.1. INTRODUCTION
3.2. THE CAPE VERDE ARCHIPELAGO
3.3. MAGMATIC PROCESSES
3.4. MAGMA STORAGE IN SOUTHERN CAPE VERDE
3.5. INSIGHTS INTO THE SHALLOWER MAGMATIC SYSTEM
3.6. OCEAN ISLANDS GLOBALLY
3.7. CONCLUSIONS AND RECOMMENDATIONS
ACKNOWLEDGMENTS
REFERENCES
4 Anatomy of Intraplate Monogenetic Alkaline Basaltic Magmatism: Clues From Magma, Crystals, and Glass
4.1. INTRODUCTION
4.2. ORIGIN OF INTRAPLATE MONOGENETIC BASALTIC SYSTEMS
4.3. INSIGHTS FROM WHOLE‐ROCK CHEMICAL DATA
4.4. INSIGHTS FROM CRYSTAL COMPOSITIONS
4.5. INSIGHTS FROM GLASS COMPOSITIONS
4.6. SUMMARY AND CONCLUDING REMARKS
ACKNOWLEDGMENTS
REFERENCES
Part II: Experimental and Numerical Constraints on Magmatic Processes
5 Magma Differentiation and Contamination: Constraints From Experimental and Field Evidences
5.1. INTRODUCTION
5.2. GEOLOGICAL AND GEOCHEMICAL INFERENCES ON FRACTIONATION
5.3. MECHANISMS OF LIQUID–CRYSTAL SEPARATION
5.4. MAGMA CONTAMINATION BY COUNTRY‐ROCK ASSIMILATION
5.5. CONCLUDING REMARKS
ACKNOWLEDGMENTS
REFERENCES
6 Crystal and Volatile Controls on the Mixing and Mingling of Magmas
6.1. INTRODUCTION: MAGMA MIXING AND MINGLING AND VOLCANIC PLUMBING SYSTEMS
6.2. CONTROLS ON MAGMA MINGLING: OBSERVATIONS, EXPERIMENTS, AND NUMERICAL MODELS
6.3. PETROLOGIC CONSTRAINTS ON MINGLING CONDITIONS: PETROGRAPHIC INTERPRETATIONS
6.4. QUANTITATIVE MODELING OF CRYSTAL AND VOLATILE CONTROLS ON MIXING AND MINGLING
6.5. CONCLUSIONS AND OUTLOOK FOR FUTURE RESEARCH
ACKNOWLEDGMENTS
REFERENCES
7 From Binary Mixing to Magma Chamber Simulator: Geochemical Modeling of Assimilation in Magmatic Systems
7.1. INTRODUCTION
7.2. THE END‐MEMBER MODES OF MAGMATIC INTERACTION
7.3. OVERVIEW OF GEOCHEMICAL MODELS OF ASSIMILATION
7.4. SUMMARY
ACKNOWLEDGMENTS
REFERENCES
Part III: Timescales of Magma Dynamics
8 Elemental Diffusion Chronostratigraphy: Time‐Integrated Insights Into the Dynamics of Plumbing Systems
8.1. INTRODUCTION
8.2. GEOSPEEDOMETRY: APPROACH AND LIMITATIONS
8.3. ISOTHERMAL VERSUS NON‐ISOTHERMAL APPROACH
8.4. THE TEMPERATURE CONUNDRUM
8.5. TWO EXAMPLES: STROMBOLI AND POPOCATÉPETL VOLCANOES
8.6. RESOLVING ELEMENTAL DIFFUSION STRATIGRAPHY
8.7. UNCERTAINTIES
8.8. CONCLUSIONS: A WAY FORWARD
ACKNOWLEDGMENTS
REFERENCES
9 Interpreting Magma Dynamics Through a Statistically Refined Thermometer: Implications for Clinopyroxene Fe–Mg Diffusion Modeling and Sector Zoning at Stromboli
9.1. INTRODUCTION
9.2. CALIBRATION AND TEST DATA SETS
9.3. PARAMETERIZATION OF THE THERMOMETER
9.4. IMPLICATIONS FOR MAGMA DYNAMICS AT STROMBOLI
9.5. FINAL REMARKS
ACKNOWLEDGMENTS
REFERENCES
10 Insights Into Processes and Timescales of Magma Storage and Ascent From Textural and Geochemical Investigations: Case Studies From High‐Risk Neapolitan Volcanoes (Italy)
10.1. INTRODUCTION
10.2. VOLCANOLOGICAL BACKGROUND OF NEAPOLITAN AREA
10.3. MAGMA EVOLUTION IN CRUSTAL RESERVOIRS
10.4. MAGMA ASCENT IN VOLCANIC CONDUIT
10.5. CONCLUSIONS: IMPLICATIONS FOR FUTURE HAZARDS

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