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The Science of Solar System Ices

  • Book
  • © 2013

Overview

Editors:
  1. Murthy S. Gudipati

    1. NASA Jet Propulsion Lab., California Institute of Technology, Pasadena, USA

    View editor publications

    You can also search for this editor in PubMed   Google Scholar

  2. Julie Castillo-Rogez

    1. NASA Jet Propulsion Lab., California Institute of Technology, Pasadena, USA

    View editor publications

    You can also search for this editor in PubMed   Google Scholar

  • First review of the properties of solar system ices published in book form since 1998
  • Covers all aspects of ice properties, and will emphasize the applications of laboratory work in supporting the interpretation of space mission observations
  • Includes articles by many renowned planetary scientists
  • Includes supplementary material: sn.pub/extras

Part of the book series: Astrophysics and Space Science Library (ASSL, volume 356)

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Table of contents (18 chapters)

  1. Front Matter

    Pages i-xiv
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  2. Optical Remote Sensing of Planetary Ices

    1. Front Matter

      Pages 1-1
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  3. OPTICAL REMOTE SENSING OF PLANETARY ICES

    1. Observed Ices in the Solar System

      • Roger N. Clark, Robert Carlson, Will Grundy, Keith Noll
      Pages 3-46

    2. Photometric Properties of Solar System Ices

      • A. J. Verbiscer, P. Helfenstein, B. J. Buratti
      Pages 47-72

    3. Ultraviolet Properties of Planetary Ices

      • A. R. Hendrix, D. L. Domingue, K. S. Noll
      Pages 73-105

    4. The Ices on Transneptunian Objects and Centaurs

      • C. de Bergh, E. L. Schaller, M. E. Brown, R. Brunetto, D. P. Cruikshank, B. Schmitt
      Pages 107-146

  4. Ice Physical Properties and Planetary Applications

    1. Front Matter

      Pages 147-147
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  5. ICE PHYSICAL PROPERTIES AND PLANETARY APPLICATIONS

    1. First-Principles Calculations of Physical Properties of Planetary Ices

      • Razvan Caracas
      Pages 149-169

    2. Frictional Sliding of Cold Ice: A Fundamental Process Underlying Tectonic Activity Within Icy Satellites

      • Erland M. Schulson
      Pages 171-181

    3. Planetary Ices Attenuation Properties

      • Christine McCarthy, Julie C. Castillo-Rogez
      Pages 183-225

    4. Creep Behavior of Ice in Polar Ice Sheets

      • Paul Duval
      Pages 227-251

    5. Cratering on Icy Bodies

      • M. J. Burchell
      Pages 253-278

    6. Geology of Icy Bodies

      • Katrin Stephan, Ralf Jaumann, Roland Wagner
      Pages 279-367

  6. Volatiles in Ices

    1. Front Matter

      Pages 369-369
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  7. VOLATILES IN ICES

    1. Amorphous and Crystalline H2O-Ice

      • Rachel M. E. Mastrapa, William M. Grundy, Murthy S. Gudipati
      Pages 371-408

    2. Clathrate Hydrates: Implications for Exchange Processes in the Outer Solar System

      • Mathieu Choukroun, Susan W. Kieffer, Xinli Lu, Gabriel Tobie
      Pages 409-454

    3. Cometary Ices

      • Carey Lisse, Akiva Bar-Nun, Diana Laufer, Michael Belton, Walter Harris, Henry Hsieh et al.
      Pages 455-485

    4. Gas Trapping in Ice and Its Release upon Warming

      • Akiva Bar-Nun, Diana Laufer, Oscar Rebolledo, Serguei Malyk, Hanna Reisler, Curt Wittig
      Pages 487-499

  8. Surface Ice Chemistry

    1. Front Matter

      Pages 501-501
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  9. SURFACE ICE CHEMISTRY

    1. Chemistry in Water Ices: From Fundamentals to Planetary Applications

      • Murthy S. Gudipati, Paul D. Cooper
      Pages 503-526
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Keywords

About this book

The role of laboratory research and simulations in advancing our understanding of solar system ices (including satellites, KBOs, comets, and giant planets) is becoming increasingly important. Understanding ice surface radiation processing, particle and radiation penetration depths, surface and subsurface chemistry, morphology, phases, density, conductivity, etc., are only a few examples of the inventory of issues that are being addressed by Earth-based laboratory research.

As a response to the growing need for cross-disciplinary dialog and communication in the Planetary Ices science community, this book aims to achieve direct dialog and foster focused collaborations among the observational, modeling, and laboratory research communities.

Editors and Affiliations

  • NASA Jet Propulsion Lab., California Institute of Technology, Pasadena, USA

    Murthy S. Gudipati, Julie Castillo-Rogez

About the editors

Murthy Gudipati is a Principal Scientist in the Planetary Ice Group, Science Division, of the Jet Propulsion Laboratory in Pasadena, California. Gudipati's research interests can be broadly defined as understanding the physics and chemistry of interstellar and Solar System ices through laboratory simulations, observations, and instrumentation or simply evolution of ices in the universe. The three wings of this space endeavor are physics and chemistry of ices with applications to biology, chemistry, atmosphere, and astrophysics; space instrumentation to analyze organic matter on planets such as Mars, Europa, Titan, and Enceladus; and observations and analysis of in-situ and remote data. Gudipati's research in the recent past has focused on physics and chemistry of cryogenic ices. This research builds on the over 15 years of earlier expertise on chemical physics / physical chemistry, spectroscopy, and photochemistry of atmospheric and organic molecules in cryogenic matrices.

Julie Castillo-Rogez is a planetary scientist in the Planetary Ices Group, Science Division, of the Jet Propulsion Laboratory, California Institute of Technology in Pasadena, California. Her main interest lies in material physics, applied to the modeling of icy satellite and asteroid geophysical evolution and the design and planning of future spaceborne and in situ observations of these objects. Castillo-Rogex is involved hands-on in the measurements of the mechanical properties of ice in JPL's Ice Physics Laboratory, which she co-founded. She is a consultant for the definition and design of frozen astromaterial simultants, simulation chambers, and instrument testbeds. Her technical publications for the past ten years cover a variety of topics ranging from the geophysics and dynamics of icy satellites to the astrobiology of asteroids and the development of strategies to explore these objects with small spacecrafts.

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