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Science (1999) Vol. 283 p 1135-1138

Science (1999) Vol. 283 p 1135-1138. Introduction.

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Science (1999) Vol. 283 p 1135-1138

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  1. Science (1999) Vol. 283 p 1135-1138

  2. Introduction • A Brief Introduction - Max• How we know polycyclic aromatic hydrocarbons are ubiquitous and abundant in space - Lou• Interstellar conditions and how we simulate them - Scott• How we analyzed the samples (L2MS) - Dick• Our results and their astrobiological significance - Max• Conclusions - Max

  3. Space was considered chemically barren for most of the 20th Century The spell was broken in the 1960’s and 1970’s with these discoveries: OH (early 60’s) NH3 (1968) H2CO (1969)* CO (1970) 11.3 µm emission (1973) A little context… * …polyatomic molecules containing at least 2 atoms other than H can form in the interstellar medium.” Snyder, Buhl, Zuckerman, Palmer

  4. Center of the Orion Nebula

  5. EMISSION FROM ORION

  6. Soot Particles are Mainly PAHS PAH MOLECULE SOOT PARTICLE

  7. Darken room and cover projector lens for fluorescence demonstration

  8. UV UV Pumped Infrared Fluorescence

  9. PAH EMISSION FROM NEARBY SPIRAL GALAXY MESSIER 81.

  10. PAH EMISSION FROM THE SOMBRERO GALAXY MESSIER 104.

  11. What happens to PAHS in Cold, Dark Interstellar Clouds ??? TOP OF THE HORSEHEAD NEBULA

  12. Astrochemistry - A middling difficult enterprise “Physicists love the early universe -- because it is EASY. You’ve got protons, electrons, light, and that’s it. Once atoms come together, you get chemistry, then biology, then economics… it pretty much goes to hell.” -Andrew Lange (5/3/2000)

  13. How do we simulate chemistry in the interstellar medium? • Much of the material in galaxies exists in ‘Dense Molecular Clouds’ that consist of a mixture of dust, gas, and ices

  14. How do we simulate the interstellar medium? • These ‘dense’ clouds are the site of star formation • Material from these clouds can find its way into/onto newly formed planets

  15. How do we simulate the interstellar medium? • The dust in these dense clouds blocks out starlight and their interiors can get very cold (T < 50 K). • The pressures are very low

  16. How do we simulate the interstellar medium? • The radiation field can be high (UV and particle radiation)•This radiation clearly illuminates PAHs associated with the clouds Visible Light PAH Emission

  17. Bernstein, Sandford, Allamandola , Sci. Am. 7,1999, p26 Interstellar Dust: ice mantle evolution Thus, at the low temperatures found in these clouds, most molecules are expected to freeze out onto the dust grains where they may be exposed to ionizing radiation

  18. We can get an idea of what the ices are made of by measuring the absorption spectra of the cloud material The main ice ingredient is always H2O.

  19. So, to simulate dense cloud conditions we need to recreate low T, low P, high radiation conditions with PAHs in H2O-rich ices exposed to radiation Cryo-vacuum Sample Head

  20. Lots of “plumbing”… Cryo-vacuum System (w/o spectrometer) H2 Lamp On

  21. Brown Organic Residue Produced by Low Temperature UV Ice Irradiation

  22. Analysis of the Samples

  23. Laser-Desorption Laser-Ionization Mass Spectrometer

  24. Two-Step Laser Mass Spectrometry A+ A A+ A B A A+ B B A A B B A B I. Laser desorption of neutral molecules II. Laser ionization of selected species selective ionization of aromatics pulsed UV laser plume of neutral molecules pulsed IR laser to detector sample

  25. Principles ofTime-of-Flight Mass Spectrometry Kinetic Energy = zV = 1/2mv2 Arrival Time = t = d/v = d/[(2z V/m)]1/2 = d[m/(2zV)]1/2

  26. Two-Step Laser Mass Spectrometry pulsed IR beam Reflectron Acceleration grids time of flight chamber pulsed UV beam Mass Deflectors Einzel lens MCP detector

  27. The peaks at 316, 332, and 348 amu correspond to the addition of one to three O atoms, respectively, likely in the form of ketones or hydroxyl side groups (or both).

  28. The peak at 290 amu corresponds to the addition of an O atom with loss of two H atoms, consistent with an ether bridging the molecule’s bay region.

  29. Summary

  30. Astrobiological Implications: The Search for Life and see a whale breaching in the oceans of Europa

  31. Astrobiological Implications: The Search for Life Alkylated PAHs were invoked as biomarkers in the Martian meteorite ALH84001 McKay et al., (1996) Science, Vol. 273, p. 924-930. "Search for past life on Mars: Possible relic biogenic activity in martian meteorite ALH84001"

  32. Astrobiological Implications: The Search for Life

  33. Astrobiological Implications: The Origin of Life We see this class of compounds facilitating the most basic chemical reactions in "primitive" organisms thus we believe that these molecules are ancient Thermoproteus tenax (a "primitive" organism) use menaquinones as their primary quinone, and in most Bacteria and Archaea, MK and related naphthoquinones seem to be very fundamental = ancient: are manufactured via Shikimate, couple important biochemical reactions (i.e. Fumarate to Succinate), are involved in active transport of amino acids, and replace or augment ubiquinone or plastoquinone as electon transport and oxidative phosphorylation co-enzymes

  34. Conclusions • The results explain many molecules seen in meteorites. • These species resemble biomarkers, and thus are relevant • to the search for life. • They are members of a class of compounds that is • ubiquitous in space. • Quinones play fundamental roles in life's chemistry now and • probably did so from the beginning.

  35. Thanks Advice, edits, and patience of our friends here at NASA-Ames and Stanford, Technical support from dedicated lab technicians, Support from our local management and, Financial support from NASA's Astrophysics and Planetary Science Divisions at NASA HQ Our thanks also to our coauthor colleagues who were unable to attend this presentation. It wouldn’t have happened without them.

  36. Prof. Zare receiving H. Julian Allen Award from Simon P. Worden, Ph.D., BGen. (USAF, Ret.), who is the Director of the NASA Ames Research Center

  37. Photo of all presenters: Simon P. Worden, Scott A. Sanford, Richard N. Zare, Max P. Berstein, and Louis J. Allamandola. Unfortunately, two other authors could not be present: J. Seb Gillette and Simon J. Clemett. (Photo by Dr. Jennifer Heldmann)

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