TY - JOUR
T1 - How to Survive at Point Nemo? Fischer–Tropsch, Artificial Photosynthesis, and Plasma Catalysis for Sustainable Energy at Isolated Habitats
AU - Levchenko, lgor
AU - Xu, Shuyan
AU - Baranov, Oleg
AU - Bazaka, Kateryna
N1 - Publisher Copyright:
© 2023 The Authors. Global Challenges published by Wiley-VCH GmbH.
PY - 2024/1
Y1 - 2024/1
N2 - Inhospitable, inaccessible, and extremely remote alike the famed pole of inaccessibility, aka Point Nemo, the isolated locations in deserts, at sea, or in outer space are difficult for humans to settle, let alone to thrive in. Yet, they present a unique set of opportunities for science, economy, and geopolitics that are difficult to ignore. One of the critical challenges for settlers is the stable supply of energy both to sustain a reasonable quality of life, as well as to take advantage of the local opportunities presented by the remote environment, e.g., abundance of a particular resource. The possible solutions to this challenge are heavily constrained by the difficulty and prohibitive cost of transportation to and from such a habitat (e.g., a lunar or Martian base). In this essay, the advantages and possible challenges of integrating Fischer-Tropsch, artificial photosynthesis, and plasma catalysis into a robust, scalable, and efficient self-contained system for energy harvesting, storage, and utilization are explored.Extremely remote places like pole of inaccessibility called Point Nemo, remote islands or outposts on Mars and Moon are difficult to settle. The critical challenge is the stable energy supply. In this essay, the possible architecture and challenges of integrating Fischer-Tropsch, artificial photosynthesis, and plasma catalysis into an efficient self-contained system for energy harvesting, storage, and utilization are explored.image
AB - Inhospitable, inaccessible, and extremely remote alike the famed pole of inaccessibility, aka Point Nemo, the isolated locations in deserts, at sea, or in outer space are difficult for humans to settle, let alone to thrive in. Yet, they present a unique set of opportunities for science, economy, and geopolitics that are difficult to ignore. One of the critical challenges for settlers is the stable supply of energy both to sustain a reasonable quality of life, as well as to take advantage of the local opportunities presented by the remote environment, e.g., abundance of a particular resource. The possible solutions to this challenge are heavily constrained by the difficulty and prohibitive cost of transportation to and from such a habitat (e.g., a lunar or Martian base). In this essay, the advantages and possible challenges of integrating Fischer-Tropsch, artificial photosynthesis, and plasma catalysis into a robust, scalable, and efficient self-contained system for energy harvesting, storage, and utilization are explored.Extremely remote places like pole of inaccessibility called Point Nemo, remote islands or outposts on Mars and Moon are difficult to settle. The critical challenge is the stable energy supply. In this essay, the possible architecture and challenges of integrating Fischer-Tropsch, artificial photosynthesis, and plasma catalysis into an efficient self-contained system for energy harvesting, storage, and utilization are explored.image
KW - Fischer–Tropsch
KW - artificial photosynthesis
KW - plasma catalysis
UR - http://www.scopus.com/inward/record.url?scp=85178436246&partnerID=8YFLogxK
U2 - 10.1002/gch2.202300086
DO - 10.1002/gch2.202300086
M3 - Article
SN - 2056-6646
VL - 8
JO - Global Challenges
JF - Global Challenges
IS - 1
M1 - 2300086
ER -