Don J. Lindler | Researchain

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Featured researches published by Don J. Lindler.

Science | 2011

EPOXI at Comet Hartley 2

Michael F. A'Hearn; Michael Belton; W. Alan Delamere; Lori Michelle Feaga; D. L. Hampton; J. Kissel; Kenneth P. Klaasen; Lucy A. McFadden; Karen J. Meech; H. Jay Melosh; Peter H. Schultz; Jessica M. Sunshine; Peter C. Thomas; Joseph Veverka; Dennis D. Wellnitz; D. K. Yeomans; Sebastien Besse; D. Bodewits; Timothy Bowling; Brian T. Carcich; Steven M. Collins; Tony L. Farnham; Olivier Groussin; Brendan Hermalyn; Michael Shawn Kelley; Jian-Yang Li; Don J. Lindler; Carey Michael Lisse; Stephanie McLaughlin; Frederic Merlin

In situ observations show that comet Hartley 2 is an unusually hyperactive comet. 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 CO2, 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.

Science | 2006

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

Jessica M. Sunshine; Michael F. A'Hearn; Olivier Groussin; J.-Y. Li; Michael J. S. Belton; W. A. Delamere; J. Kissel; Kenneth P. Klaasen; Lucy A. McFadden; Karen J. Meech; H. J. Melosh; Peter H. Schultz; Peter C. Thomas; J. Veverka; D. K. Yeomans; I. Busko; M. Desnoyer; Tony L. Farnham; Lori Michelle Feaga; D. L. Hampton; Don J. Lindler; C. M. Lisse; Dennis D. Wellnitz

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.

Proceedings of SPIE | 2010

Development and utilization of a point spread function for the Extrasolar Planet Observation and Characterization/Deep Impact Extended Investigation (EPOXI) Mission

R. K. Barry; Don J. Lindler; L. D. Deming; Michael F. A'Hearn; Sarah Ballard; Brian T. Carcich; D. Charbonneau; Jessie L. Christiansen; Tilak Hewagama; Lucy A. McFadden; Dennis D. Wellnitz

The Extrasolar Planet Observation Characterization and the Deep Impact Extended Investigation missions (EPOXI) are currently observing the transits of exoplanets, a comet nucleus at short range, and Earth using the High Resolution Instrument (HRI) - a 0.3 m f/35 telescope - on the Deep Impact flyby spacecraft. The HRI is in a permanently defocused state with the instrument point of focus about 0.6 cm before the focal plane due to the use of a reference flat mirror that became a powered optic due to thermal warping during ground thermal-vacuum testing. Consequently, the point spread function (PSF) covers approximately nine pixels FWHM and is characterized by a patch with three-fold symmetry due to the three-point support structures of the primary and secondary mirrors. The PSF is also strongly color dependent varying in shape and size with change in filtration and target color. While defocus is highly desirable for exoplanet transit observations to limit sensitivity to intra-pixel variation, it is suboptimal for observations of spatially resolved targets. Consequently, all images used in our analysis of such objects were deconvolved with an instrument PSF. The instrument PSF is also being used to optimize transit analysis. We discuss development and usage of an instrument PSF for these observations.

Icarus | 2013

A distribution of large particles in the coma of Comet 103P/Hartley 2

Michael Shawn Kelley; Don J. Lindler; D. Bodewits; Michael F. A'Hearn; Carey Michael Lisse; Ludmilla Kolokolova; J. Kissel; Brendan Hermalyn

Icarus | 2013

Shape, density, and geology of the nucleus of Comet 103P/Hartley 2

Peter C. Thomas; Michael F. A'Hearn; Joseph Veverka; Michael Belton; J. Kissel; Kenneth P. Klaasen; Lucy A. McFadden; H. Jay Melosh; Peter H. Schultz; Sebastien Besse; Brian T. Carcich; Tony L. Farnham; Olivier Groussin; Brendan Hermalyn; Jian-Yang Li; Don J. Lindler; Carey Michael Lisse; Karen J. Meech; James E. Richardson

Icarus | 2013

The complex spin state of 103P/Hartley 2: Kinematics and orientation in space

Michael Belton; Peter C. Thomas; Jian-Yang Li; Jade L. Williams; Brian T. Carcich; Michael F. A’Hearn; Stephanie McLaughlin; Tony L. Farnham; Lucy A. McFadden; Carey Michael Lisse; Steven M. Collins; Sebastien Besse; Kenneth P. Klaasen; Jessica M. Sunshine; Karen J. Meech; Don J. Lindler

Icarus | 2013

The detection, localization, and dynamics of large icy particles surrounding Comet 103P/Hartley 2

Brendan Hermalyn; Tony L. Farnham; Steven M. Collins; Michael Shawn Kelley; Michael F. A’Hearn; D. Bodewits; Brian T. Carcich; Don J. Lindler; C. M. Lisse; Karen J. Meech; Peter H. Schultz; Peter C. Thomas

Icarus | 2007