Predicted Versus Observed Cosmic-ray-produced Noble Gases in Lunar Samples
Predicted Versus Observed Cosmic-ray-produced Noble Gases in Lunar Samples

Author:

Publisher:

Published: 1979

Total Pages:

ISBN-13:

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New sets of cross sections for the production of krypton isotopes from targets of Rb, Sr, Y, and Zr were constructed primarily on the bases of experimental excitation functions for Kr production from Y. These cross sections were used to calculate galactic-cosmic-ray and solar-proton production rates for Kr isotopes in the moon. Spallation Kr data obtained from ilmenite separates of rocks 10017 and 10047 are reported. Production rates and isotopic ratios for cosmogenic Kr observed in ten well-documented lunar samples and in ilmenite separates and bulk samples from several lunar rocks with long but unknown irradiation histories were compared with predicted rates and ratios. The agreements were generally quite good. Erosion of rock surfaces affected rates or ratios for only near-surface samples, where solar-proton production is important. There were considerable spreads in predicted-to-observed production rates of 83Kr, due at least in part to uncertainties in chemical abundances. The 78Kr/83Kr ratios were predicted quite well for samples with a wide range of Zr/Sr abundance ratios. The calculated 8°Kr/83Kr ratios were greater than the observed ratios when production by the 79Br(n, .gamma.) reaction was included, but were slightly undercalculated if the Br reaction was omitted; these results suggest that Br(n, .gamma.)-produced Kr is not retained well by lunar rocks. The productions of 81Kr and 82Kr were overcalculated by approximately 10% relative to 83Kr. Predicted-to-observed 84Kr/83 ratios scattered considerably, possibly because of uncertainties in corrections for trapped and fission components and in cross sections for 84Kr production. Most predicted 84Kr and 86Kr production rates were lower than observed. Shielding depths of several Apollo 11 rocks were determined from the measured 78Kr/83Kr ratios of ilmenite separates. 4 figures, 5 tables.

Lunar Sourcebook
Lunar Sourcebook

Author: Grant Heiken

Publisher: CUP Archive

Published: 1991-04-26

Total Pages: 796

ISBN-13: 9780521334440

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The only work to date to collect data gathered during the American and Soviet missions in an accessible and complete reference of current scientific and technical information about the Moon.

Apollo 12 Preliminary Science Report
Apollo 12 Preliminary Science Report

Author: Manned Spacecraft Center (U.S.)

Publisher:

Published: 1970

Total Pages: 246

ISBN-13:

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The Apollo 11 Mission, primarily designed to land men on the Moon and return them safely to Earth, signaled a new phase of the manned space program. Based on the success of Apollo 11, the first of a series of missions designed for the systematic exploration of the Moon was successfully accomplished on Apollo 12. The fact that the Apollo 12 astronauts were able to achieve a pinpoint landing at a preselected site, and then spend an extended time on the lunar surface, graphically illustrates the rapid progress of the Apollo program. The Apollo 12 mission added significantly to man's knowledge of the Moon. The precise landing capability allowed the crew to accomplish a wide variety of preplanned tasks and paved the way for planning future missions to smaller, more selected landing areas with the possibility of significant scientific returns. The publication includes chapters on mission description, summary of scientific results, photographic summary of the Apollo 12 Mission, crew observations, passive seismic experiment, lunar surface magnetometer experiment, the solar-wind spectrometer experiment, suprathermal ion detector experiment (lunar ionosphere detector), cold cathode gage (lunar atmosphere detector), the solar-wind composition experiment, Apollo 12 multispectral photography experiment, preliminary geologic investigation of the Apollo 12 landing site, lunar surface closeup stereoscopic photography, preliminary examination of lunar samples, and preliminary results from Surveyor 3 analysis.

Noble Gases
Noble Gases

Author: Donald P. Porcelli

Publisher: Walter de Gruyter GmbH & Co KG

Published: 2018-12-17

Total Pages: 864

ISBN-13: 1501509055

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Volume 47 of Reviews in Mineralogy and Geochemistry introduces to Noble Gases. Although the mass spectrometry principles are not complex, the tricks involved in getting better data are often self taught or passed on by working with individuals who themselves are pushing the boundaries further. Furthermore, much of the exciting new science is linked with technical developments that allow us to move beyond the current measurement capabilities. Be they better crushing devices, laser resonance time of flight, multiple collection or compressor sources - the technical issues are central to progress. Contents: Noble Gases – Noble Science An Overview of Noble Gas Geochemistry and Cosmochemistry Noble Gases in the Solar System Noble Gases in the Moon and Meteorites: Radiogenic Components and Early Volatile Chronologies Cosmic-Ray-Produced Noble Gases in Meteorites Martian Noble Gases Origin of Noble Gases in the Terrestrial Planets Noble Gas Isotope Geochemistry of Mid-Ocean Ridge and Ocean Island Basalts: Characterization of Mantle Source Reservoirs Noble Gases and Volatile Recycling at Subduction Zones The Storage and Transport of Noble Gases in the Subcontinental Lithosphere Models for the Distribution of Terrestrial Noble Gases and the Evolution of the Atmosphere Production, Release and Transport of Noble Gases in the Continental Crust Tracing Fluid Origin, Transport and Interaction in the Crust Noble Gases in Lakes and Ground Waters Noble Gases in Ocean Waters and Sediments Cosmic-Ray-Produced Noble Gases in Terrestrial Rocks: Dating Tools for Surface Processes K-Ar and Ar-Ar Dating (U-Th)/He Dating: Techniques, Calibrations, and Applications

Reconstructing Past Earth and Planetary Surface Temperatures with Cosmogenic Noble Gases
Reconstructing Past Earth and Planetary Surface Temperatures with Cosmogenic Noble Gases

Author: Marissa M. Tremblay

Publisher:

Published: 2017

Total Pages: 137

ISBN-13:

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Cosmogenic nuclides, which are produced in the uppermost few meters of the Earth's crust by cosmic-ray particle interactions with atomic nuclei, are commonly used to quantify the rates and timing of surface processes. Some of the first terrestrial cosmogenic nuclide measurements revealed that the cosmogenic noble gases 3He and 21Ne are diffusively lost at Earth surface temperatures in common silicate minerals like quartz and feldspars. Viewed as a fatal limitation for geologic applications since then, the open-system behavior of cosmogenic noble gases can, in fact, be exploited to quantitatively reconstruct temperatures at the surfaces of Earth and other planetary bodies. In Chapter 1, I develop a theoretical framework for using cosmogenic noble gases as a paleothermometer based on the principles and mathematics underlying radiogenic noble gas thermochronometry. With this framework and published information on the diffusion kinetics of helium and neon in quartz and feldspars, I demonstrate that cosmogenic 3He-in-quartz measurements could be used to constrain past surface temperatures at high latitudes and elevations on Earth, while 21Ne-in-feldspar measurements could be used to constrain past surface temperatures at lower latitudes and elevations, and on other planetary bodies. I then explore the applicability of these published diffusion kinetics through a series of stepwise degassing experiments on quartz (Chapter 2) and feldspars (Chapter 3) containing initially uniform distributions of proton-induced 3He and 21Ne. These experiments reveal that 3He and 21Ne diffusion kinetics vary significantly across samples of different geologic origin, and that in many cases quartz and feldspars exhibit complex diffusion behavior mani- fest as nonlinearity in Arrhenius plots. The origin of this complex behavior is indeterminate, but I demonstrate that it is not caused by temperature-dependent structural transformations or anisotropy and that it is not an artifact of proton irradiation. Instead, complex diffusion behavior appears to be controlled by some intrinsic, sample-specific material property. I also demonstrate that we can mathematically model complex diffusion behavior, and use geologic examples with simple exposure and temperature histories to validate this mathematical model. Having laid out the theoretical and experimental backbone of cosmogenic noble gas paleothermometry, in Chapter 4 I present two applications of the technique to problems in paleoclimate and planetary science. In the first application, I use cosmogenic 3He and 10Be observations in quartz from a series of nested moraines in the Maritime Italian Alps to reconstruct temperatures since the Last Glacial Maximum (LGM). I demonstrate that temperatures reconstructed from the cosmogenic 3He observations are consistent with temperatures expected for this region since the LGM from a global circulation model (GCM) and other proxy data, but that additional constraints are necessary to fully interpret this dataset. In the second application, I use observations of cosmogenic neon isotopes in plagioclase feldspars from lunar sample 76535 to demonstrate that this sample only experienced solar heating during its 142 million year residency at the lunar surface. This constraint on the thermal history of 76535 agrees with existing argon measurements and confirms the fidelity of paleomagnetic measurements in the same sample, which have been used to demonstrate that the Moon had an early core dynamo.