Your search keyword '"Feaga LM"' showing total 4 results

1. EPOXI at comet Hartley 2.

Author

A'Hearn MF, Belton MJ, Delamere WA, Feaga LM, Hampton D, Kissel J, Klaasen KP, McFadden LA, Meech KJ, Melosh HJ, Schultz PH, Sunshine JM, Thomas PC, Veverka J, Wellnitz DD, Yeomans DK, Besse S, Bodewits D, Bowling TJ, Carcich BT, Collins SM, Farnham TL, Groussin O, Hermalyn B, Kelley MS, Kelley MS, Li JY, Lindler DJ, Lisse CM, McLaughlin SA, Merlin F, Protopapa S, Richardson JE, and Williams JL

Abstract

Understanding how comets work--what drives their activity--is crucial to the use of comets in studying the early solar system. EPOXI (Extrasolar Planet Observation and Deep Impact Extended Investigation) flew past comet 103P/Hartley 2, one with an unusually small but very active nucleus, taking both images and spectra. Unlike large, relatively inactive nuclei, this nucleus is outgassing primarily because of CO(2), which drags chunks of ice out of the nucleus. It also shows substantial differences in the relative abundance of volatiles from various parts of the nucleus.

Published

2011

2. Temporal and spatial variability of lunar hydration as observed by the Deep Impact spacecraft.

Author

Sunshine JM, Farnham TL, Feaga LM, Groussin O, Merlin F, Milliken RE, and A'Hearn MF

Subjects

Extraterrestrial Environment, Spacecraft, Spectrum Analysis, Sunlight, Temperature, Time Factors, Hydroxyl Radical, Moon, Water

Abstract

The Moon is generally anhydrous, yet the Deep Impact spacecraft found the entire surface to be hydrated during some portions of the day. Hydroxyl (OH) and water (H2O) absorptions in the near infrared were strongest near the North Pole and are consistent with <0.5 weight percent H2O. Hydration varied with temperature, rather than cumulative solar radiation, but no inherent absorptivity differences with composition were observed. However, comparisons between data collected 1 week (a quarter lunar day) apart show a dynamic process with diurnal changes in hydration that were greater for mare basalts (approximately 70%) than for highlands (approximately 50%). This hydration loss and return to a steady state occurred entirely between local morning and evening, requiring a ready daytime source of water-group ions, which is consistent with a solar wind origin.

Published

2009

3. Spitzer spectral observations of the deep impact ejecta.

Author

Lisse CM, Vancleve J, Adams AC, A'hearn MF, Fernández YR, Farnham TL, Armus L, Grillmair CJ, Ingalls J, Belton MJ, Groussin O, McFadden LA, Meech KJ, Schultz PH, Clark BC, Feaga LM, and Sunshine JM

Abstract

Spitzer Space Telescope imaging spectrometer observations of comet 9P/Tempel 1 during the Deep Impact encounter returned detailed, highly structured, 5- to 35-micrometer spectra of the ejecta. Emission signatures due to amorphous and crystalline silicates, amorphous carbon, carbonates, phyllosilicates, polycyclic aromatic hydrocarbons, water gas and ice, and sulfides were found. Good agreement is seen between the ejecta spectra and the material emitted from comet C/1995 O1 (Hale-Bopp) and the circumstellar material around the young stellar object HD100546. The atomic abundance of the observed material is consistent with solar and C1 chondritic abundances, and the dust-to-gas ratio was determined to be greater than or equal to 1.3. The presence of the observed mix of materials requires efficient methods of annealing amorphous silicates and mixing of high- and low-temperature phases over large distances in the early protosolar nebula.

Published

2006

4. Exposed water ice deposits on the surface of comet 9P/Tempel 1.

Author

Sunshine JM, A'Hearn MF, Groussin O, Li JY, Belton MJ, Delamere WA, Kissel J, Klaasen KP, McFadden LA, Meech KJ, Melosh HJ, Schultz PH, Thomas PC, Veverka J, Yeomans DK, Busko IC, Desnoyer M, Farnham TL, Feaga LM, Hampton DL, Lindler DJ, Lisse CM, and Wellnitz DD

Subjects

Spectrophotometry, Infrared, Ice analysis, Meteoroids

Abstract

We report the direct detection of solid water ice deposits exposed on the surface of comet 9P/Tempel 1, as observed by the Deep Impact mission. Three anomalously colored areas are shown to include water ice on the basis of their near-infrared spectra, which include diagnostic water ice absorptions at wavelengths of 1.5 and 2.0 micrometers. These absorptions are well modeled as a mixture of nearby non-ice regions and 3 to 6% water ice particles 10 to 50 micrometers in diameter. These particle sizes are larger than those ejected during the impact experiment, which suggests that the surface deposits are loose aggregates. The total area of exposed water ice is substantially less than that required to support the observed ambient outgassing from the comet, which likely has additional source regions below the surface.

Published

2006