The UK Centre for Astrobiology: A Virtual Astrobiology Centre. Accomplishments and Lessons Learned, 2011–2016

Little is known of the effects of ionizing radiation exposure on soil biota. We exposed soil microcosms to weekly bursts of 60 Co gamma radiation over six weeks, at three levels of exposure (0.1 kGy/hr/wk [low], 1 kGy/hr/wk [medium] and 3 kGy/hr/wk [high]). Soil DNA was extracted, and shotgun metagenomes were sequenced and characterised using MG-RAST. We hypothesized that with increasing radiation exposure there would be a decrease in both taxonomic and functional diversity. While bacterial diversity decreased, diversity of fungi and algae unexpectedly increased, perhaps because of release from competition. Despite the decrease in diversity of bacteria and of biota overall, functional gene diversity of algae, bacteria, fungi and total biota increased. Cycles of radiation exposure may increase the range of gene functional strategies viable in soil, a novel ecological example of the effects of stressors or disturbance events promoting some aspects of diversity. Moreover, repeated density-independent population crashes followed by population expansion may allow lottery effects, promoting coexistence. Radiation exposure produced large overall changes in community composition. Our study suggests several potential novel radiation-tolerant groups: in addition to Deinococcus-Thermus, which reached up to 20% relative abundance in the metagenome, the phyla Chloroflexi (bacteria), Chytridiomycota (fungi) and Nanoarcheota (archaea) may be considered as radiation-tolerant.

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“…Cockell et al . 57 has suggested that even normal background levels of radiation may be a significant long-term factor in soil systems.…”

Section: Introductionmentioning

confidence: 99%

Changes in soil taxonomic and functional diversity resulting from gamma irradiation

Ogwu

Kerfahi

Song

et al. 2019

Sci Rep

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“…The Science and Technology Facilities Council's (STFC) Boulby Underground Laboratory (BUL) sits at approximately 1,070-1,100 m below ground surface [27,28] within Boulby mine, a potash and polyhalite mine operated by Israel Chemicals Limited, in North Yorkshire. BUL, begun in 1988, was motivated by the search for dark matter [27] and hosts experiments requiring low background radiation conditions [28][29][30][31][32]. The background activity from radionuclide contamination (gamma radiation) is particularly low (approximately 0.1 ppm of uranium and thorium and 1,130 ppm of potassium) [27].…”

Section: The Boulby Underground Laboratorymentioning

confidence: 99%

Battery Earth: using the subsurface at Boulby underground laboratory to investigate energy storage technologies

Daniels,

Harrington,

Wiseall

et al. 2023

Front. Phys.

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Renewable energy provides a low-carbon alternative to power generation in the UK. However, the resultant supply varies on daily, weekly and seasonal cycles, such that for green energies to be fully exploited new grid-scale energy storage systems must be implemented. Two pilot facilities in Germany and the United States have demonstrated the potential of the Earth as a battery to store compressed air, using off-peak surplus energy. Natural accumulations of salt (halite deposits) in the UK represent a large and untapped natural storage reservoir for compressed air with the ability to provide instantaneous green energy to meet peak demand. To realise the potential of this emerging technology, a detailed knowledge of the relationship between mechanics, chemistry and geological properties is required to optimise cavern design, storage potential and economic feasibility. The variable stresses imposed on the rock matrix by gas storage, combined with the cyclic nature of cavern pressurisation are barriers to deployment that need to be addressed to enable large-scale adoption of schemes. Well-designed field experiments are a lynchpin for advancing research in this area, especially when supported by state-of-the-art characterisation and modelling techniques. The research facility at STFC’s Boulby Underground Laboratory presents the ideal location to tackle these fundamental issues to optimise “Battery Earth”.

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“…美国NASA天体生物学研究所自成立之初就要求每个成员机构必须开展本科生/研究生/博士后教育以及中小学生和公众的科普宣传 [17] . 英国天体生物学研究中心把教育(大学生和中小学生等)、培训(中小学教师和航天员等)和公众科普作为其主要发展方向之一 [116] .…”

Section: 行星开发与行星保护unclassified

Overview and perspectives of Astrobiology

Lin¹,

Li²,

Wang³

et al. 2019

Chin. Sci. Bull.

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The UK Centre for Astrobiology: A Virtual Astrobiology Centre. Accomplishments and Lessons Learned, 2011–2016

Cited by 6 publications

References 93 publications

Changes in soil taxonomic and functional diversity resulting from gamma irradiation

Changes in soil taxonomic and functional diversity resulting from gamma irradiation

Battery Earth: using the subsurface at Boulby underground laboratory to investigate energy storage technologies

Overview and perspectives of Astrobiology

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