Your search keyword '"Cockell, Charles S."' showing total 10 results

1. Habitable worlds with no signs of life

Author

Cockell, Charles S.

Published

2014

2. Minimum Units of Habitability and Their Abundance in the Universe.

Author

Cockell, Charles S., Wordsworth, Robin, Whiteford, Niall, and Higgins, Peter M.

Subjects

*MAXIMA & minima, *EXTRASOLAR planets, *CHARTS, diagrams, etc., *HYPOTHESIS, UNIVERSE

Abstract

Although the search for habitability is a much-vaunted objective in the study of planetary environments, the material requirements for an environment to be habitable can be met with relatively few ingredients. In this hypothesis paper, the minimum material requirements for habitability are first re-evaluated, necessarily based on life "as we know it." From this vantage point, we explore examples of the minimum number of material requirements for habitable conditions to arise in a planetary environment, which we illustrate with "minimum habitability diagrams." These requirements raise the hypothesis that habitable conditions may be common throughout the universe. If the hypothesis was accepted, then the discovery of life would remain an important discovery, but habitable conditions on their own would be an unremarkable feature of the material universe. We discuss how minimum units of habitability provide a parsimonious way to consider the minimum number of geological inferences about a planetary body, and the minimum number of atmospheric components that must be measured, for example in the case of exoplanets, to be able to make assessments of habitability. [ABSTRACT FROM AUTHOR]

Published

2021

3. Nonphotosynthetic Pigments as Potential Biosignatures.

Author

Schwieterman, Edward W., Cockell, Charles S., and Meadows, Victoria S.

Subjects

*PHOTOSYNTHETIC pigments, *BIOSIGNATURES (Origin of life), *PHOTOSYNTHESIS, *EXTRASOLAR planets, *HALOPHILIC microorganisms

Abstract

Previous work on possible surface reflectance biosignatures for Earth-like planets has typically focused on analogues to spectral features produced by photosynthetic organisms on Earth, such as the vegetation red edge. Although oxygenic photosynthesis, facilitated by pigments evolved to capture photons, is the dominant metabolism on our planet, pigmentation has evolved for multiple purposes to adapt organisms to their environment. We present an interdisciplinary study of the diversity and detectability of nonphotosynthetic pigments as biosignatures, which includes a description of environments that host nonphotosynthetic biologically pigmented surfaces, and a lab-based experimental analysis of the spectral and broadband color diversity of pigmented organisms on Earth. We test the utility of broadband color to distinguish between Earth-like planets with significant coverage of nonphotosynthetic pigments and those with photosynthetic or nonbiological surfaces, using both 1-D and 3-D spectral models. We demonstrate that, given sufficient surface coverage, nonphotosynthetic pigments could significantly impact the disk-averaged spectrum of a planet. However, we find that due to the possible diversity of organisms and environments, and the confounding effects of the atmosphere and clouds, determination of substantial coverage by biologically produced pigments would be difficult with broadband colors alone and would likely require spectrally resolved data. Key Words: Biosignatures-Exoplanets-Halophiles-Pigmentation-Reflectance spectroscopy-Spectral models. Astrobiology 15, 341-361. [ABSTRACT FROM AUTHOR]

Published

2015

4. Uninhabited habitats on Mars

Author

Cockell, Charles S., Balme, Matt, Bridges, John C., Davila, Alfonso, and Schwenzer, Susanne P.

Subjects

*SPACE colonies, *BIOSPHERE, *MARTIAN meteorites, *GEOCHEMISTRY, *MARS (Planet), *MARTIAN atmosphere, *EARTH (Planet)

Abstract

Abstract: Investigations of Mars as a potential location for life often make the assumption that where there are habitats, they will contain organisms. However, the observation of the ubiquitous distribution of life in habitable environments on the Earth does not imply the presence of life in martian habitats. Although uninhabited habitats are extremely rare on the Earth, a lack of a productive photosynthetic biosphere on Mars to generate organic carbon and oxygen, thus providing a rapidly available redox couple for energy acquisition by life and/or a lack of connectivity between habitats potentially increases the scope and abundance of uninhabited habitats for much of the geological history of the planet. Uninhabited habitats could have existed on Mars from the Noachian to the present-day in impact hydrothermal systems, megaflood systems, lacustrine environments, transient melted permafrost, gullies and local regions of volcanic activity; and there may be evidence for them in martian meteorites. Uninhabited habitats would provide control habitats to investigate the role of biology in planetary-scale geochemical processes on the Earth and they would provide new constraints on the habitability of Mars. Future robotic craft and samples returned from Mars will be able to directly show if uninhabited habitats exist or existed on Mars. [Copyright &y& Elsevier]

Published

2012

5. Interstellar planetary protection

Author

Cockell, Charles S.

Subjects

*DETECTION of extrasolar planets, *SPACE vehicles, *SPACE exploration, *ASTRONAUTICS, *SPACE environment, *ASTROPHYSICS, *OUTER space

Abstract

Abstract: In the coming decades the detection of Earth-like extrasolar planets, either apparently lifeless or exhibiting spectral signatures of life, will encourage design studies for craft to visit them. These missions will require the elaboration of an interstellar planetary protection protocol. Given a specific dose required to sterilize microorganisms on a spacecraft, a critical mean velocity can be determined below which a craft becomes self-sterilizing. This velocity is calculated to be below velocities previously projected for interstellar missions, suggesting that an active sterilization protocol prior to launch might be required. Given uncertainties in the surface conditions of a destination extrasolar planet, particularly at microscopic scales, the potential for unknown biochemistries and biologies elsewhere, or the possible inoculation of a lifeless planet that is habitable, then both lander and orbiter interstellar missions should be completely free of all viable organisms, necessitating a planetary protection approach applied to orbiters and landers bound for star systems with unknown local conditions for habitability. I discuss the case of existing craft on interstellar trajectories – Pioneer 10, 11 and Voyager 1 and 2. [Copyright &y& Elsevier]

Published

2008

6. The Ethical Relevance of Earth-like Extrasolar Planets.

Author

Cockell, Charles S.

Subjects

*EXTRASOLAR planets, *SPECTROSCOPIC imaging, *ENVIRONMENTAL ethics, *BIOSPHERE, *STARS, *LIFE (Biology), *ATMOSPHERE, *ECOLOGY, *EARTH (Planet)

Abstract

The discovery of Earth-sized extrasolar planets orbiting distant stars will merit an expansion of the sphere of entities worthy of moral consideration. Although it will be a long time, if ever, before humans visit these planets, it is nevertheless worthwhile to develop an environmental ethic that encompasses these planets, as this ethic reflects on our view of life on Earth and elsewhere. A particularly significant case would be a planet that displays spectroscopic signatures of life, although the discovery of many lifeless planets might itself intensify the value of life on Earth. A derivation of Schweitzer's general principle of "reverence for life" and similar frameworks are appropriate ethics with which to view extrasolar planets. The development of an ethical framework for extrasolar planets might provide a means to fashion a deeper and more effective environmental ethic for Earth's biosphere. [ABSTRACT FROM AUTHOR]

Published

2006

7. Zones of photosynthetic potential on Mars and the early Earth

Author

Cockell, Charles S. and Raven, John A.

Subjects

*ULTRAVIOLET radiation, *PHOTOSYNTHESIS, *MARS (Planet), *EARTH (Planet)

Abstract

Ultraviolet radiation is more damaging on the surface of Mars than on Earth because of the lack of an ozone shield. We investigated micro-habitats in which UV radiation could be reduced to levels similar to those found on the surface of present-day Earth, but where light in the photosynthetically active region (400–700 nm) would be above the minimum required for photosynthesis. We used a simple radiative transfer model to study four micro-habitats in which such a theoretical Martian Earth-like Photosynthetic Zone (MEPZ) might exist. A favorable radiation environment was found in martian soils containing iron, encrustations of halite, polar snows and crystalline rocks shocked by asteroid or comet impacts, all of which are known habitats for phototrophs on Earth. Although liquid water and nutrients are also required for life, micro-environments with favorable radiation environments for phototrophic life exist in a diversity of materials on Mars. This finding suggests that the lack of an ozone shield is not in itself a limit to the biogeographically widespread colonization of land by photosynthetic organisms, even if there are no other UV-absorbers in the atmosphere apart from carbon dioxide. When applied to the Archean Earth, these data suggest that even with the worst-case assumptions about the UV radiation environment, early land masses could have been colonized by primitive photosynthetic organisms. Such zones could similarly exist on anoxic extra-solar planets lacking ozone shields. [Copyright &y& Elsevier]

Published

2004

8. Linking Methanogenesis in Low-Temperature Hydrothermal Vent Systems to Planetary Spectra: Methane Biosignatures on an Archean-Earth-like Exoplanet.

Author

Seeburger, Rhys, Higgins, Peter M., Whiteford, Niall P., and Cockell, Charles S.

Subjects

*HYDROTHERMAL vents, *BIOSIGNATURES (Origin of life), *PLANETARY systems, *ATMOSPHERIC methane, *OCEAN bottom, *METHANE, *PHOTOSYNTHETICALLY active radiation (PAR), *EXTRASOLAR planets

Abstract

In this work, the viability of the detection of methane produced by microbial activity in low-temperature hydrothermal vents on an Archean-Earth-like exoplanet in the habitable zone is explored via a simplified bottom-up approach using a toy model. By simulating methanogens at hydrothermal vent sites in the deep ocean, biological methane production for a range of substrate inflow rates was determined and compared to literature values. These production rates were then used, along with a range of ocean floor vent coverage fractions, to determine likely methane concentrations in the simplified atmosphere. At maximum production rates, a vent coverage of 4–15 × 10−4 % (roughly 2000–6500 times that of modern Earth) is required to achieve 0.25% atmospheric methane. At minimum production rates, 100% vent coverage is not enough to produce 0.25% atmospheric methane. NASA's Planetary Spectrum Generator was then used to assess the detectability of methane features at various atmospheric concentrations. Even with future space-based observatory concepts (such as LUVOIR and HabEx), our results show the importance of both mirror size and distance to the observed planet. Planets with a substantial biomass of methanogens in hydrothermal vents can still lack a detectable, convincingly biological methane signature if they are beyond the scope of the chosen instrument. This work shows the value of coupling microbial ecological modeling with exoplanet science to better understand the constraints on biosignature gas production and its detectability. [ABSTRACT FROM AUTHOR]

Published

2023

9. Exoplanet Biosignatures: A Review of Remotely Detectable Signs of Life.

Author

Schwieterman, Edward W., Kiang, Nancy Y., Parenteau, Mary N., Harman, Chester E., DasSarma, Shiladitya, Fisher, Theresa M., Arney, Giada N., Hartnett, Hilairy E., Reinhard, Christopher T., Olson, Stephanie L., Meadows, Victoria S., Cockell, Charles S., Walker, Sara I., Grenfell, John Lee, Hegde, Siddharth, Rugheimer, Sarah, Renyu Hu, and Lyons, Timothy W.

Subjects

*EXTRASOLAR planets, *BIOSIGNATURES (Origin of life), *BIOSPHERE, *GEOLOGICAL time scales, *ATMOSPHERE

Abstract

In the coming years and decades, advanced space- and ground-based observatories will allow an unprecedented opportunity to probe the atmospheres and surfaces of potentially habitable exoplanets for signatures of life. Life on Earth, through its gaseous products and reflectance and scattering properties, has left its fingerprint on the spectrum of our planet. Aided by the universality of the laws of physics and chemistry, we turn to Earth's biosphere, both in the present and through geologic time, for analog signatures that will aid in the search for life elsewhere. Considering the insights gained from modern and ancient Earth, and the broader array of hypothetical exoplanet possibilities, we have compiled a comprehensive overview of our current understanding of potential exoplanet biosignatures, including gaseous, surface, and temporal biosignatures. We additionally survey biogenic spectral features that are well known in the specialist literature but have not yet been robustly vetted in the context of exoplanet biosignatures. We briefly review advances in assessing biosignature plausibility, including novel methods for determining chemical disequilibrium from remotely obtainable data and assessment tools for determining the minimum biomass required to maintain short-lived biogenic gases as atmospheric signatures. We focus particularly on advances made since the seminal review by Des Marais et al. The purpose of this work is not to propose new biosignature strategies, a goal left to companion articles in this series, but to review the current literature, draw meaningful connections between seemingly disparate areas, and clear the way for a path forward. [ABSTRACT FROM AUTHOR]

Published

2018

10. In Search of Future Earths: Assessing the Possibility of Finding Earth Analogues in the Later Stages of Their Habitable Lifetimes.

Author

O'Malley-James, Jack T., Greaves, Jane S., Raven, John A., and Cockell, Charles S.

Subjects

*HABITABLE zone (Outer space), *GEOCHEMICAL cycles, *EXTRASOLAR planets, *BIOSIGNATURES (Origin of life), *SURFACE temperature

Abstract

Earth will become uninhabitable within 2-3 Gyr as a result of the increasing luminosity of the Sun changing the boundaries of the habitable zone (HZ). Predictions about the future of habitable conditions on Earth include declining species diversity and habitat extent, ocean loss, and changes to geochemical cycles. Testing these predictions is difficult, but the discovery of a planet that is an analogue to future Earth could provide the means to test them. This planet would need to have an Earth-like biosphere history and to be approaching the inner edge of the HZ at present. Here, we assess the possibility of finding such a planet and discuss the benefits of analyzing older Earths. Finding an old-Earth analogue in nearby star systems would be ideal, because this would allow for atmospheric characterization. Hence, as an illustrative example, G stars within 10 pc of the Sun are assessed as potential old-Earth-analog hosts. Six of these represent good potential hosts. For each system, a hypothetical Earth analogue is placed at locations within the continuously habitable zone (CHZ) that would allow enough time for Earth-like biosphere development. Surface temperature evolution over the host star's main sequence lifetime (assessed by using a simple climate model) is used to determine whether the planet would be in the right stage of its late-habitable lifetime to exhibit detectable biosignatures. The best candidate, in terms of the chances of planet formation in the CHZ and of biosignature detection, is 61 Virginis. However, planet formation studies suggest that only a small fraction (0.36%) of G stars in the solar neighborhood could host an old-Earth analogue. If the development of Earth-like biospheres is rare, requiring a sequence of low-probability events to occur, biosphere evolution models suggest they are rarer still, with only thousands being present in the Galaxy as a whole. Key Words: Extrasolar terrestrial planets-Habitable zone-Planetary environments-Habitability. Astrobiology 15, 400-411. [ABSTRACT FROM AUTHOR]

Published

2015