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 .p156 [[ https://en.wikipedia.org/wiki/Sample_Analysis_at_Mars | Sample Analysis at Mars (SAM) ]] on [[ https://en.wikipedia.org/wiki/Mars_Science_Laboratory | Mars Science Laboratory ]] [[ https://en.wikipedia.org/wiki/Curiosity_(rover) | Curiosity Rover ]]
 .p161 [[ | ]]
 
 .p156 [[ https://en.wikipedia.org/wiki/Sample_Analysis_at_Mars | Sample Analysis at Mars (SAM) ]] on [[ https://en.wikipedia.org/wiki/Mars_Science_Laboratory | Mars Science Laboratory ]] [[ https://en.wikipedia.org/wiki/Curiosity_(rover) | Curiosity Rover ]] found 0.4 ppb methane.
 .p157 [[ https://en.wikipedia.org/wiki/European_Space_Agency | ESA ]] [[ https://en.wikipedia.org/wiki/ExoMars | ExoMars ]] [[ https://en.wikipedia.org/wiki/Trace_Gas_Orbiter | Trace Gas Orbiter ]] found nothing up to 2019
 .p157 [[ https://en.wikipedia.org/wiki/European_Space_Agency | ESA ]][[ https://en.wikipedia.org/wiki/Mars_Express | Mars Express Orbiter ]] reported a [[ https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2018JE005824 | methane spike above Gale crater in 2019 ]]
 .p161 [[ https://en.wikipedia.org/wiki/Perseverance_(rover) | Perseverance ]] samples dried up river delta on west rim of [[ https://en.wikipedia.org/wiki/Jezero_(crater) | Jezero Crater ]] 2022 May, [[ https://en.wikipedia.org/wiki/NASA-ESA_Mars_Sample_Return | sample return mission planned ]] after 2033
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 .p172 [[ | ]]
 .p174 [[ | ]]
 .p172 [[ https://www.space.com/jupiter-moon-europa-water-vapor-confirmed.html | sporadic Europa water vapor plumes (2019) ]]
 .p174 charged particles bombarding Europa produce [[ https://www.nasa.gov/missions/juno/nasas-juno-mission-measures-oxygen-production-at-europa/ | 40 tonnes of oxygen per hour ]] over Europa's 1e13 square meter surface
  . Europa surface temperature 50K to 140K, oxygen will be gas, not liquid or solid
  . Europa escape velocity 2 km/s, rms thermal velocity less than 400 m/s, but charged particle bombardment might remove it
  . Europa atmospheric density 2.4e18 to 14e18 atoms per square meter, 24 to 140 micrograms per square meter.

Is Earth Exceptional?

The Quest for Cosmic Life

  • Mario Livio & Jack Szostak . 2024 . 576.83 LIVIO . Cedar Mill Library


  • Chemistry escapes me. Too many un-descriptive "historical" names for processes, substances, molecules. Hence chapters 2, 3, and 4 are as difficult to internalize as lists of the crowned heads of Europe (and the wars they started, won, and mostly lost)


  • p001 Chapter 1: A Freak Chemical Accident or a Cosmic Imperative?

  • p022 Galileo: "I do not feel obligated to believe that the same God who has given us our senses, reason, and intelligence, wishes us to abandon their use"




  • p067 Appendix: Chemical Structures and Reactions

  • p073 Chapter 4: The Origin of Life: Amino Acids and Peptides


  • p083 Chapter 5: The Origin of Life: The Road to the Protocell

  • p087 dipolar membrane molecules amphiphilic, hydrophobic and hydrophilic ends, self-assembly of bilayer membranes

  • p087 early Earth environment origin difficult to explain
  • p089 fatty acids spontaneously assemble into bilayers in water, model protocells

  • p091 Alexander Oparin proposed coaverate aggregates of polymers

  • p091 RNA molecules might have "colonized" the surface of mineral particles, but attraction forces distort them
  • p092 condensation of nucleotides into chains is endothermic in water, hydrolyzing separation exothermic
  • p093 Drying RNA in warm CO₂ can polymerize, but carbonic acid breaks bonds
  • p094 Leslie Orgel

  • p094 imidazole activated nucleotide release

  • p094 leaving group detaches during reaction

  • p095 growing ice crystals concentrates dissolved compounds between them
  • p096 alkaline carbonate lakes concentrate dissolved phosphate

  • p097 perhaps suitable environments for nucleotide and RNA synthesis
  • p100 Szostak Lab U. Chicago chemistry depertment

  • p101 non-enzymatic RNA copying very different from biological copying
  • p101 spending months in the laboratory can save you several hours in the library
  • p102 imidazole-activated dinucleotide, "bridged substrate"

  • p103 higher copying at lower concentrations
  • p104 similarities to replication of simpler RNA viruses infecting bacteria, but simpler
  • p105 circular genome avoids starting/ending point, viroids

  • p106 beginning replication methods would not have been complex
  • p106 virtual circular genome model VCG

  • p107 temperature cycling separates and joins randomly, copying in different places, eventually complete replication
    • hypothetical, testing under way
  • p107 Albert Eschenmoser hypothetical progenitor nucleic acid that led to RNA

  • p108 showed a diverse collection of artificial nucleic acids can be viable genetic polymers
  • p108 ANA arabinose nucleic acid TNA threose nucleic acid

  • p108 Whatever the original nucleic acid, RNA always wins; the copying process preferentially generates RNA
  • p109 fatty acid membranes highly permeable to inbound nutrients and outbound wastes without evolved pores or channels
  • p109 experiments demonstrate primordial cells can grow and divide in many different ways
  • p109 micelles, molecular aggregates that can grow and divide

  • p110 growing membranes vary in shape, leading to budding and new vesicles
  • p111 osmotic pressure swells RNA-filled vesicles with water and more RNA
  • p111 "competitive growth" favors protocells containing RNA that replicates faster
  • p112 increased concentration outside the protocell reduces osmotic pressure, reshapes the vesicle, perhaps dividing it
  • p112 divalent magnesium citrate can protect a protocell from rupture

  • p112 doesn't effect fatty acid membranes
  • p113 membranes also stabilized by ribose and adenine nucleotides
  • p113 Sarah Keller University of Washington slkeller@uw.edu, B.A. Physics Rice 1989, PhD Biophysics Princeton 1995

  • p117 easiest-to-make amino acids tend to pair-bond strongly
  • p117 genetic code partly deterministic, partly "frozen historical accident"

  • p119 Chapter 6: Putting it All Together: From Astrophysics and Geology to Chemistry and Biology

  • p135 Many chemical processes only at surface, evidence of surface origin of like, NOT hydrothermal vents
  • p136 experiment show temperature cycles enable seemingly contradictory requirements.
  • p136 environment cycling between high and low temperatures seems required for nonenzymatic RNA replication
  • p137 Darwin's prescient "warm little pond"; volcanic hot springs, and asteroid impact craters
  • p138 evolving ribozymes requires maintenance of larger genome
  • p138 hypothetical life on Mars might originate from impact ejecta; 12% of Chixhulub ejecta reached Earth escape velocity



  • p167 Chapter 8: Extraterrestrial Life on Solar System Moons?

  • p172 sporadic Europa water vapor plumes (2019)

  • p174 charged particles bombarding Europa produce 40 tonnes of oxygen per hour over Europa's 1e13 square meter surface

    • Europa surface temperature 50K to 140K, oxygen will be gas, not liquid or solid
    • Europa escape velocity 2 km/s, rms thermal velocity less than 400 m/s, but charged particle bombardment might remove it
    • Europa atmospheric density 2.4e18 to 14e18 atoms per square meter, 24 to 140 micrograms per square meter.
  • p177

  • p178

  • p179

  • p180

  • p180

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  • p187


  • p189 Chapter 9: Life Out There: The Astronomical Quest

  • p194

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  • p200

  • p200

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  • p216

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  • p219 Chapter 10: Life as We Don't Know It: The Design of Natural and Unnatural Life-Forms

  • p221

  • p223

  • p225


  • p231 Chapter 11: The Hunt for Intelligence: Preliminary Thoughts

  • p233

  • p233

  • p237

  • p238

  • p242

  • p245

  • p250

  • p251

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  • p257 Chapter 12: The Hunt for Intelligence: The Searches

  • p259

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  • p271 Chapter 13: Epilogue: And Immanent Breakthrough?

  • p272

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  • p277

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  • p279

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  • p285 Acknowledgements


  • p287 Selected Further Reading
  • p301 Lustin-Yaeger et. al. 2018, "Detecting Ocean Glint on Exoplanets Using Multiphase Mapping," Astronomical Journal 156 no. 6 December


  • p311 Index

EarthExceptional (last edited 2026-05-23 08:33:33 by KeithLofstrom)