Your search keyword '"Kristen Stubbs"' showing total 6 results

1. Application of pulsed-excitation fluorescence imager for daylight detection of sparse life in tests in the Atacama Desert

Author

L. E. Dansey, Lauren A. Ernst, David Wettergreen, Kristen Stubbs, Geb Thomas, Gian Gabriele Ori, Alan S. Waggoner, Jeffrey E. Moersch, James M. Dohm, Stuart Heys, Charles S. Cockell, G. Chong Diaz, Gregory W. Fisher, Frederick Lanni, Peter Coppin, Lucia Marinangeli, D. Pane, Andrew N. Hock, S. Weinstein, Edmond A. Grin, J. L. Piatek, Trey Smith, Nathalie A. Cabrol, E. Minkley, S. Emani, Michael Wagner, K. Warren-Rhodes, and James Teza

Subjects

In situ, Atmospheric Science, Ecology, business.industry, Paleontology, Soil Science, Forestry, Field tests, Aquatic Science, Oceanography, Fluorescence, Fluorescence intensity, Geophysics, Optics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Environmental science, Daylight, business, Chlorophyll fluorescence, Earth-Surface Processes, Water Science and Technology, Remote sensing

Abstract

A daylight fluorescence imager was deployed on an autonomous rover, Zoe, to detect life on the surface and shallow subsurface in regions of the Atacama Desert in Chile during field tests between 2003 and 2005. In situ fluorescent measurements were acquired from naturally fluorescing biomolecules such as chlorophyll and from specific fluorescent probes sprayed on the samples, targeting each of the four biological macromolecule classes: DNA, protein, lipid, and carbohydrate. RGB context images were also acquired. Preparatory reagents were applied to enhance the dye probe penetration and fluorescence intensity of chlorophyll. Fluorescence imager data sets from 257 samples were returned to the Life in the Atacama science team. A variety of visible life forms, such as lichens, were detected, and several of the dye probes produced signals from nonphotosynthetic microorganisms.

Published

2008

2. Life in the Atacama: A scoring system for habitability and the robotic exploration for life

Author

Gregory W. Fisher, Trey Smith, Geb Thomas, Gian Gabriele Ori, James M. Dohm, Jeffrey E. Moersch, Kristen Stubbs, E. Minkley, Michael Wagner, S. Weinstein, Mike Wyatt, Erin Pudenz, K. Warren-Rhodes, Peter Coppin, Lauren A. Ernst, David Wettergreen, Justin M. Glasgow, Charles S. Cockell, Andrew N. Hock, Nathalie A. Cabrol, David R. Thompson, J. L. Piatek, Edmond A. Grin, Alan S. Waggoner, Dominic Jonak, Craig Hardgrove, and Lucia Marinangeli

Subjects

Atmospheric Science, Scoring system, Soil Science, Aquatic Science, Oceanography, Exploration of Mars, Strength of evidence, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Life detection, Earth-Surface Processes, Water Science and Technology, Ecology, Habitability, business.industry, Environmental resource management, Paleontology, Forestry, Variance (accounting), Mars Exploration Program, Geophysics, Space and Planetary Science, Environmental science, Physical geography, Metric (unit), business

Abstract

[1] The science goals of the Life in the Atacama (LITA) robotic field experiment are to understand habitat and seek out life in the Atacama Desert, Chile, as an analog to future missions to Mars. To those ends, we present a new data analysis tool, the LITA Data Scoring System (DSS), which (1) integrates rover and orbital data relevant to environmental habitability and life detection, and (2) provides a standard metric, or “score” to evaluate (a) the potential habitability, and (b) the strength of evidence for life at all locales along the rover's traverse. Designed and tested during the 2005 field campaign, first results from the DSS indicate that the three selected sites in the Atacama Desert are generally inhospitable. The strength of evidence for life is positively correlated with potential habitability at two of the three sites. Using factor analysis, we find three factors explain 79.9% of the variance in biological observations and five factors explain 96.2% of the variance in potential habitability across all sites. These factors are used to focus a discussion of scoring variable definitions for future robotic missions in the Atacama and of instrument selection and strategy development for future robotic missions on Earth and Mars.

Published

2007

3. Surface and subsurface composition of the Life in the Atacama field sites from rover data and orbital image analysis

Author

Lucia Marinangeli, Orion Carlisle, Geb Thomas, Craig Hardgrove, David Wettergreen, Dominic Jonak, Michael Wagner, Michael L. Rampey, Peter Coppin, Erin Pudenz, K. Warren-Rhodes, Gian Gabriele Ori, Jeffrey E. Moersch, Trey Smith, Kristen Stubbs, Nathalie A. Cabrol, Justin M. Glasgow, Edmond A. Grin, Andrew N. Hock, Guillermo Chong Diaz, J. L. Piatek, Michael B. Wyatt, S. Weinstein, D. M. Drake, Charles S. Cockell, and James M. Dohm

Subjects

Atmospheric Science, Infrared, Soil Science, Mineralogy, Terrain, Aquatic Science, Oceanography, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Neutron detection, Earth-Surface Processes, Water Science and Technology, Remote sensing, geography, geography.geographical_feature_category, Ecology, Near-infrared spectroscopy, Paleontology, Forestry, Mars Exploration Program, VNIR, Mars rover, Geophysics, Volcano, Space and Planetary Science, Geology

Abstract

[1] The Life in the Atacama project examined six different sites in the Atacama Desert (Chile) over 3 years in an attempt to remotely detect the presence of life with a rover. The remote science team, using only orbital and rover data sets, identified areas with a high potential for life as targets for further inspection by the rover. Orbital data in the visible/near infrared (VNIR) and in the thermal infrared (TIR) were used to examine the mineralogy, geomorphology, and chlorophyll potential of the field sites. Field instruments included two spectrometers (VNIR reflectance and TIR emission) and a neutron detector: this project represents the first time a neutron detector has been used as part of a “science-blind” rover field test. Rover-based spectroscopy was used to identify the composition of small scale features not visible in the orbital images and to improve interpretations of those data sets. The orbital and ground-based data sets produced consistent results, suggesting that much of the field sites consist of altered volcanic terrains with later deposits of sulfates, quartz, and iron oxides. At one location (Site A), the ground-based spectral data revealed considerably greater compositional diversity than was seen from the orbital view. One neutron detector transect provided insight into subsurface hydrogen concentrations, which correlated with life and surface features. The results presented here have implications for targeting strategies, especially for future Mars rover missions looking for potential habitats/paleohabitats.

Published

2007

4. Robotic ecological mapping: Habitats and the search for life in the Atacama Desert

Author

Chong Diaz, E. Minkley, Geb Thomas, D. Pane, S. Weinstein, Kristen Stubbs, L. Ng Boyle, James M. Dohm, Edmond A. Grin, Trey Smith, Nathalie A. Cabrol, Gregory W. Fisher, Alan S. Waggoner, J. L. Piatek, G. G. Oril, Michael Wagner, K. Warren-Rhodes, Peter Coppin, Andrew N. Hock, M. Wyatt, Jeffrey E. Moersch, Lauren A. Ernst, David Wettergreen, and S. Emani

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Alluvial fan, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Spatial distribution, Geophysics, Habitat, Space and Planetary Science, Geochemistry and Petrology, Abundance (ecology), Ecohydrology, Earth and Planetary Sciences (miscellaneous), Landscape ecology, Transect, Lichen, Geology, Earth-Surface Processes, Water Science and Technology

Abstract

[1] As part of the three-year ‘Life in the Atacama’ (LITA) project, plant and microbial abundance were mapped within three sites in the Atacama Desert, Chile, using an automated robotic rover. On-board fluorescence imaging of six biological signatures (e.g., chlorophyll, DNA, proteins) was used to assess abundance, based on a percent positive sample rating system and standardized robotic ecological transects. The percent positive rating system scored each sample based on the measured signal strength (0 for no signal to 2 for strong signal) for each biological signature relative to the total rating possible. The 2005 field experiment results show that percent positive ratings varied significantly across Site D (coastal site with fog), with patchy zones of high abundance correlated with orbital and microscale habitat types (heaved surface crust and gravel bars); alluvial fan habitats generally had lower abundance. Non-random multi-scale biological patchiness also characterized interior desert Sites E and F, with relatively high abundance associated with (paleo)aqueous habitats such as playas. Localized variables, including topography, played an important, albeit complex, role in microbial spatial distribution. Site D biosignature trends correlated with culturable soil bacteria, with MPN ranging from 10-1000 CFU/g-soil, and chlorophyll ratings accurately mapped lichen/moss abundance (Site D) and higher plant (Site F) distributions. Climate also affected biological patchiness, with significant correlation shown between abundance and (rover) air relative humidity, while lichen patterns were linked to the presence of fog. Rover biological mapping results across sites parallel longitudinal W-E wet/dry/wet Atacama climate trends. Overall, the study highlights the success of targeting of aqueousassociated habitats identifiable from orbital geology and mineralogy. The LITA experience also suggests the terrestrial study of life and its distribution, particularly the fields of landscape ecology and ecohydrology, hold critical lessons for the search for life on other planets. Their applications to robotic sampling strategies on Mars should be further exploited.

Published

2007

5. Life in the Atacama: Searching for life with rovers (science overview)

Author

Peter Coppin, Charles S. Cockell, Gregory W. Fisher, E. Minkley, Gian Gabriele Ori, Jeffrey E. Moersch, Alan S. Waggoner, Dominic Jonak, Erin Pudenz, Kristen Stubbs, Trey Smith, Cecilia Demergasso, Lucia Marinangeli, Geb Thomas, Guillermo Chong Diaz, Lauren A. Ernst, David Wettergreen, Craig Hardgrove, David R. Thompson, Edmond A. Grin, S. Weinstein, Nathalie A. Cabrol, Justin M. Glasgow, Andrew N. Hock, James M. Dohm, J. L. Piatek, Michael R. Wyatt, Michael Wagner, and K. Warren-Rhodes

Subjects

Scientific instrument, Atmospheric Science, Ecology, Paleontology, Soil Science, Forestry, Mars Exploration Program, Aquatic Science, Oceanography, Exploration of Mars, Arid, Geophysics, Habitat, Space and Planetary Science, Geochemistry and Petrology, Homogeneous, Earth and Planetary Sciences (miscellaneous), Environmental science, Mapping techniques, Transect, Earth-Surface Processes, Water Science and Technology, Remote sensing

Abstract

[1] The Life in the Atacama project investigated the regional distribution of life and habitats in the Atacama Desert of Chile. We sought to create biogeologic maps through survey traverses across the desert using a rover carrying biologic and geologic instruments. Elements of our science approach were to: Perform ecological transects from the relatively wet coastal range to the arid core of the desert; use converging evidence from science instruments to reach conclusions about microbial abundance; and develop and test exploration strategies adapted to the search of scattered surface and shallow subsurface microbial oases. Understanding the ability of science teams to detect and characterize microbial life signatures remotely using a rover became central to the project. Traverses were accomplished using an autonomous rover in a method that is technologically relevant to Mars exploration. We present an overview of the results of the 2003, 2004, and 2005 field investigations. They include: The confirmed identification of microbial habitats in daylight by detecting fluorescence signals from chlorophyll and dye probes; the characterization of geology by imaging and spectral measurement; the mapping of life along transects; the characterization of environmental conditions; the development of mapping techniques including homogeneous biological scoring and predictive models of habitat location; the development of exploration strategies adapted to the search for life with an autonomous rover capable of up to 10 km of daily traverse; and the autonomous detection of life by the rover as it interprets observations on-the-fly and decides which targets to pursue with further analysis.

Published

2007

6. Searching for microbial life remotely: Satellite-to-rover habitat mapping in the Atacama Desert, Chile

Author

M. Wyatt, J. L. Piatek, Chong Diaz, James M. Dohm, G. G. Oril, D. Pane, S. Emani, Kimberley A. Warren-Rhodes, Dimitrios Apostolopoulos, Jeffrey E. Moersch, E. Minkley, S. Weinstein, Kristen Stubbs, Lauren A. Ernst, David Wettergreen, Michael Wagner, Alan S. Waggoner, Nathalie A. Cabrol, Gordon Thomas, Andrew N. Hock, Gregory W. Fisher, Edmond A. Grin, Peter Coppin, Charles S. Cockell, and Trey Smith

Subjects

Atmospheric Science, Evaporite, Earth science, Soil Science, Aquatic Science, Oceanography, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Satellite imagery, Lichen, Earth-Surface Processes, Water Science and Technology, geography, geography.geographical_feature_category, Ecology, Alluvial fan, Paleontology, Forestry, Mars Exploration Program, Arid, Geophysics, Habitat, Space and Planetary Science, Sedimentary rock, Geology

Abstract

[1] The Atacama Desert, one of the most arid landscapes on Earth, serves as an analog for the dry conditions on Mars and as a test bed in the search for life on other planets. During the Life in the Atacama (LITA) 2004 field experiment, satellite imagery and ground-based rover data were used in concert with a ‘follow-the-water’ exploration strategy to target regions of biological interest in two (1 coastal, 1 inland) desert study sites. Within these regions, environments were located, studied and mapped with spectroscopic and fluorescence imaging (FI) for habitats and microbial life. Habitats included aqueous sedimentary deposits (e.g., evaporites), igneous materials (e.g., basalt, ash deposits), rock outcrops, drainage channels and basins, and alluvial fans. Positive biological signatures (chlorophyll, DNA, protein) were detected at 81% of the 21 locales surveyed with the FI during the long-range, autonomous traverses totaling 30 km. FI sensitivity in detecting microbial life in extreme deserts explains the high percentage of positives despite the low actual abundance of heterotrophic soil bacteria in coastal (

Published

2007