Neutrino and EM asterometric detection of habitable exoplanets

Neutrino and EM asterometric detection of habitable exoplanets

Discovering habitable exoplanets and exomoons increases the possibility of detecting extraterrestrial life. A bilateral approach, using neutrino and electromagnetic (EM) radiation technologies, can be used to simultaneously characterize star types that generally have exoplanets and exomoons. This in...

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Veröffentlicht in:Bioinformation 2023-03, Vol.19 (3), p.235-237
1. Verfasser: Shapshak, Paul
Format: Artikel
Sprache:eng
Schlagworte:
Artificial intelligence
Black holes
Deep space
Dwarf stars
Electromagnetic radiation
Extrasolar moons
Extrasolar planets
Extraterrestrial intelligence
Extraterrestrial life
Extraterrestrial radiation
Neutrinos
Planets
Radiation
Red giant stars
Solar system
Space exploration
Stars
Supernovae
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Zusammenfassung:Discovering habitable exoplanets and exomoons increases the possibility of detecting extraterrestrial life. A bilateral approach, using neutrino and electromagnetic (EM) radiation technologies, can be used to simultaneously characterize star types that generally have exoplanets and exomoons. This includes cool main-sequence, sub-giant, and red-giant stars. Additionally, supernovae, black holes, and neutron and dwarf stars, will be included to widen the investigation, since they sometimes have companions, including stars and planets. Currently, space exploration is advancing beyond the solar system and proliferating into deep space. For this expansion, sophisticated artificial intelligence (AI) is required and being developed for self-coordination and interactive regulation of the various exploratory vehicles and telescopes. [1-6]
ISSN:0973-8894
0973-2063
0973-2063
DOI:10.6026/97320630019235