An ESA roadmap for geobiology in space exploration

Cousins, C. R.; Cockell, Charles S.

doi:10.1016/j.actaastro.2015.10.022

Cited by 15 publications

(5 citation statements)

References 52 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In the case of copper, biomining accounts for more than 20% of the yearly worldwide production (Yin et al, 2018). These facts give a promising outlook on the application of biomining in space exploration (Cousins and Cockell, 2016). Lab-scale experiments on the interaction between bacteria and lunar regolith simulant confirm this expectation (Navarrete et al, 2013).…”

Section: Introductionmentioning

confidence: 79%

Mining moon & mars with microbes: Biological approaches to extract iron from Lunar and Martian regolith

Volger

Pettersson

Brouns

et al. 2020

Planetary and Space Science

View full text Add to dashboard Cite

Section: Introductionmentioning

confidence: 79%

Mining moon & mars with microbes: Biological approaches to extract iron from Lunar and Martian regolith

Volger

Pettersson

Brouns

et al. 2020

Planetary and Space Science

View full text Add to dashboard Cite

“…The UK Centre for Astrobiology was the lead organization on the ESA Geobiology in Space Exploration (GESE) Topical team (Cousins et al, 2015 ), a group established with funding from ESA for 3 years to consider the applied use of microbes in space with a special focus on the use of microbe-mineral interactions. This 3-year UKCA-led phase was a continuation of a prior 3-year iteration of this network (Cockell, 2010 ).…”

Section: Researchmentioning

confidence: 99%

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

et al. 2018

View full text Add to dashboard Cite

The UK Centre for Astrobiology (UKCA) was set up in 2011 as a virtual center to contribute to astrobiology research, education, and outreach. After 5 years, we describe this center and its work in each of these areas. Its research has focused on studying life in extreme environments, the limits of life on Earth, and implications for habitability elsewhere. Among its research infrastructure projects, UKCA has assembled an underground astrobiology laboratory that has hosted a deep subsurface planetary analog program, and it has developed new flow-through systems to study extraterrestrial aqueous environments. UKCA has used this research backdrop to develop education programs in astrobiology, including a massive open online course in astrobiology that has attracted over 120,000 students, a teacher training program, and an initiative to take astrobiology into prisons. In this paper, we review these activities and others with a particular focus on providing lessons to others who may consider setting up an astrobiology center, institute, or science facility. We discuss experience in integrating astrobiology research into teaching and education activities. Key Words: Astrobiology—Centre—Education—Subsurface—Analog research. Astrobiology 18, 224–243.

show abstract

“…Colonization on planets other than Earth, however, is not simple, and there are many obstacles to overcome. One of the major issues is food availability [1]. There are various options to grow food on Mars or the Moon, such as inner substrates with a nutrient solution as the medium, or aeroponics [2].…”

Section: Introductionmentioning

confidence: 99%

Ion-Exchanged Clinoptilolite as a Substrate for Space Farming

Kalvachev,

Vitale,

Arena

et al. 2024

Agriculture

View full text Add to dashboard Cite

Clinoptilolite, with its structural peculiarities (ion-exchange and adsorbent properties), is an excellent candidate for direct use and various modifications. In this study, we explored the effect of ion exchange and the particle size of clinoptilolite on Raphanus sativus seed germination, plant growth, physiological and biochemical characteristics of plants. Plants were grown, for three consecutive runs, on non-modified clinoptilolite, 0.9–2.5 mm (C-2.5) and 2.5–5.0 mm (C-5.0); clinoptilolite fractions modified with ion exchange with ammonium (CNH4-2.5 and CNH4-5.0); and potassium (CK-2.5 and CK-5.0) ions. Our data revealed that ion exchange with ammonium increased water-holding capacity, while potassium exchange decreased the water-holding capacity of the substrates irrespective of their particle size. The positive effect of small fractions ion-exchanged clinoptilolite (CNH4-2.5 and CK-2.5) on seed germination, during the third run, was established. The small clinoptilolite fractions favored root crop production, particularly in CK-2.5 plants only during the first run. Substantial positive effect on the content of total carbohydrates and polyphenols especially during the third run was established in plants grown on potassium-exchanged clinoptilolite. Our findings support the future exploration of clinoptilolite as a suitable substrate for plant growth in space and ground-based facilities for space-oriented experiments.

show abstract

An ESA roadmap for geobiology in space exploration

Cited by 15 publications

References 52 publications

Mining moon & mars with microbes: Biological approaches to extract iron from Lunar and Martian regolith

Mining moon & mars with microbes: Biological approaches to extract iron from Lunar and Martian regolith

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

Ion-Exchanged Clinoptilolite as a Substrate for Space Farming

Contact Info

Product

Resources

About