K. E. Kerry
University of Arizona
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Featured researches published by K. E. Kerry.
Space Science Reviews | 2004
William V. Boynton; W. C. Feldman; I. G. Mitrofanov; Larry G. Evans; Robert C. Reedy; S. W. Squyres; Richard D. Starr; Jack I. Trombka; C. d'Uston; J.R. Arnold; P.A.J. Englert; Albert E. Metzger; H. Wänke; J. Brückner; Darrell M. Drake; C. Shinohara; C. Fellows; David K. Hamara; K. Harshman; K. E. Kerry; Carl Turner; M. Ward; H. Barthe; K.R. Fuller; S. A. Storms; G. W. Thornton; J. L. Longmire; M. L. Litvak; A.K. Ton'chev
The Mars Odyssey Gamma-Ray Spectrometer is a suite of three different instruments, a gamma subsystem (GS), a neutron spectrometer, and a high-energy neutron detector, working together to collect data that will permit the mapping of elemental concentrations on the surface of Mars. The instruments are complimentary in that the neutron instruments have greater sensitivity to low amounts of hydrogen, but their signals saturate as the hydrogen content gets high. The hydrogen signal in the GS, on the other hand, does not saturate at high hydrogen contents and is sensitive to small differences in hydrogen content even when hydrogen is very abundant. The hydrogen signal in the neutron instruments and the GS have a different dependence on depth, and thus by combining both data sets we can infer not only the amount of hydrogen, but constrain its distribution with depth. In addition to hydrogen, the GS determines the abundances of several other elements. The instruments, the basis of the technique, and the data processing requirements are described as are some expected applications of the data to scientific problems.
Journal of Geophysical Research | 2001
William V. Boynton; S. H. Bailey; David K. Hamara; Michael S. Williams; Rolfe C. Bode; Michael R. Fitzgibbon; WenJeng Ko; M. G. Ward; K. R. Sridhar; Jeff A. Blanchard; Ralph D. Lorenz; Randy D. May; David A. Paige; A. V. Pathare; David A. Kring; Laurie A. Leshin; Douglas W. Ming; Aaron P. Zent; D. C. Golden; K. E. Kerry; H. Vern Lauer; Richard C. Quinn
The Thermal and Evolved Gas Analyzer (TEGA) on the Mars Polar Lander spacecraft is composed of two separate components which are closely coupled: a Differential Scanning Calorimeter (DSC) and an Evolved Gas Analyzer (EGA). TEGA has the capability of performing differential scanning calorimetry on eight small (0.038 mL) soil samples selected in the vicinity of the lander. The samples will be heated in ovens to temperatures up to 950°C, and the volatile compounds water and carbon dioxide, which are released during the heating, will be analyzed in the EGA. The power required by the sample oven is continuously monitored during the heating and compared to that required to heat simultaneously a similar, but empty, oven. The power difference is the output of the DSC. Both endothermic and exothermic phase transitions can be detected, and the data can be used in the identification of the phases present. By correlating the gas release with the calorimetry, the abundance of the volatile compounds associated with the different phases can be determined. The EGA may also be able to detect the release of oxygen associated with any superoxide that may be on the surface of the soil grains. The instrument can detect the melting of ice in the DSC down to abundances on the order of 0.2% of the sample, and it can detect the decomposition of calcite, CaCO3, down to abundances of 0.5%. Using the EGA, TEGA can detect small amounts of water, down to 8 ppm in the sample, and it can detect the associated release of CO2 down to the equivalent abundances of 0.03%. The EGA also has the ability to determine the 13C/12C ratio in the evolved CO2, but it is not clear if the accuracy of this ratio will be sufficient to address the scientific issues.
Journal of Geophysical Research | 2007
William V. Boynton; G. J. Taylor; Larry G. Evans; Robert C. Reedy; Richard D. Starr; Daniel M. Janes; K. E. Kerry; Darrell M. Drake; Kyeong Ja Kim; R. M. S. Williams; M. K. Crombie; James M. Dohm; Victor R. Baker; Albert E. Metzger; Suniti Karunatillake; John Michael Keller; Horton E. Newsom; James R. Arnold; J. Brückner; P.A.J. Englert; O. Gasnault; Ann L. Sprague; I. G. Mitrofanov; S. W. Squyres; Jack I. Trombka; L.C. D'Uston; H. Wänke; David K. Hamara
Journal of Geophysical Research | 2007
G. Jeffrey Taylor; William V. Boynton; J. Brückner; H. Wänke; G. Dreibus; K. E. Kerry; John Michael Keller; Robert C. Reedy; Larry G. Evans; Richard D. Starr; Steven W. Squyres; Suniti Karunatillake; O. Gasnault; S. Maurice; C. d'Uston; P. A. J. Englert; James M. Dohm; Victor R. Baker; Dave Hamara; Daniel M. Janes; Ann L. Sprague; Kyeong Ja Kim; Darrell M. Drake
Journal of Geophysical Research | 2007
John Michael Keller; William V. Boynton; Suniti Karunatillake; Victor R. Baker; James M. Dohm; Larry G. Evans; Michael Finch; Brian C. Hahn; David K. Hamara; Daniel M. Janes; K. E. Kerry; Horton E. Newsom; Robert C. Reedy; Ann L. Sprague; S. W. Squyres; Richard D. Starr; G. J. Taylor; R. M. S. Williams
Journal of Geophysical Research | 2007
Nora J. Kelly; William V. Boynton; K. E. Kerry; David K. Hamara; Daniel M. Janes; Robert C. Reedy; Kyeong Ja Kim; Robert M. Haberle
Science | 2004
Ann L. Sprague; William V. Boynton; K. E. Kerry; Daniel M. Janes; D. M. Hunten; K. J. Kim; Robert C. Reedy; Albert E. Metzger
Journal of Geophysical Research | 2003
W. C. Feldman; T. H. Prettyman; William V. Boynton; James R. Murphy; S. W. Squyres; Suniti Karunatillake; Sylvestre Maurice; R. L. Tokar; G. W. McKinney; David K. Hamara; Nora J. Kelly; K. E. Kerry
Journal of Geophysical Research | 2007
Larry G. Evans; Robert C. Reedy; Richard D. Starr; K. E. Kerry; William V. Boynton
Journal of Geophysical Research | 2007
Suniti Karunatillake; Steven W. Squyres; G. Jeffrey Taylor; John Michael Keller; O. Gasnault; Larry G. Evans; Robert C. Reedy; Richard D. Starr; William V. Boynton; Daniel M. Janes; K. E. Kerry; James M. Dohm; Ann L. Sprague; Brian C. Hahn; Dave Hamara
