Fine-tuning and interstellar chemistry

doi:10.1017/CBO9780511536557.019

17 - Fine-tuning and interstellar chemistry

Published online by Cambridge University Press: 18 December 2009

William Klemperer

Edited by

John D. Barrow ,

Simon Conway Morris ,

Stephen J. Freeland and

Charles L. Harper, Jr

Show author details

William Klemperer: Affiliation:
Department of Chemistry and Chemical Biology, Harvard University
John D. Barrow: Affiliation:
University of Cambridge
Simon Conway Morris: Affiliation:
University of Cambridge
Stephen J. Freeland: Affiliation:
University of Maryland, Baltimore
Charles L. Harper, Jr: Affiliation:
John Templeton Foundation

Book contents

Get access

Summary

Our knowledge of the universe is steadily expanding. In large measure, this has been a result of radioastronomical observations. Among the most important is that the majority of the radiation of the universe is almost uniform and follows the spectral distribution of a thermal source at a temperature of 2.725 K. This cosmic background radiation is the remnant of the initial event, the Big Bang. Although this radiation is essentially uniformly distributed in the universe, the distribution of matter is highly non-uniform.

Matter, 99% hydrogen and helium, is found virtually entirely within galaxies. Galaxies occupy 10−7 of the volume of the universe, but contain most of the known matter. The origin of this separation of radiation and matter is a topic of much current study, as is the question of galaxy formation and the abundance and distribution of intergalactic matter. Although they are clearly fundamental to the question of the chemistry that occurs, it is not my intent or capability to discuss these most interesting questions (see Peebles, 1993). The heterogeneous distributions of matter occur universally. The average density within galaxies is 1 atom of hydrogen cm3, whereas outside of galaxies estimates are of less than 1 atom of hydrogen m3 in intergalactic regions. This sharp aggregation of matter means that the chemistry is occurring within galaxies. It is sensible to focus the discussion, therefore, primarily on the molecular abundances and the chemistry occurring in our galaxy, the Milky Way, because observations are much easier in view of the decrease of radiation intensity as the inverse square of the distance.

Type: Chapter
Information: Fitness of the Cosmos for Life
Biochemistry and Fine-Tuning
, pp. 366 - 383

DOI: https://doi.org/10.1017/CBO9780511536557.019 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2007

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Adams, W. S. (1949). Observations of interstellar H and K, molecular lines, and radial velocities in the spectra of 300 O and B stars. Astrophysical Journal, 109, 354.CrossRef Google Scholar

Bertoldi, F., Cox, P., Neri, R.et. al. (2003). High-excitation CO in a quasar host galaxy at z = 6.42. Astronomy and Astrophysics, 409, L47.CrossRef Google Scholar

Bortolot, J., Clauser, J. F. and Thaddeus, P. (1969). Upper limits to the intensity of background radiation at λ = 1.32, 0.559, and 0.359 mm. Physical Review Letters, 22, 307.CrossRef Google Scholar

Buhl, D. and Snyder, L. E. (1970). Unidentified interstellar microwave line. Nature, 228, 267.CrossRef Google Scholar PubMed

Cheung, A. C., Rank, D. M., Townes, C. H.et al. (1968). Detection of NH3 molecules in the interstellar medium by their nicrowave emission. Physical Review Letters, 21, 1701.CrossRef Google Scholar

Cobb, C. (2002). Magick, Mayhem and Mavericks. Amherst, MA: Prometheus Books.Google Scholar

Downes, D. and Solomon, P. M. (2003). Molecular gas and dust at z=2.6 in SMM J14011+0252: a strongly lensed ultraluminous galaxy, not a huge massive disk. Astrophysical Journal, 582, 37.CrossRef Google Scholar

Ewen, H. I. and Purcell, E. M. (1951). Radiation from hyperfine levels of interstellar hydrogen. Astronomical Journal, s56, 125.Google Scholar

Gautier, T. N., Fink, U., Treffers, R. P.et al. (1976). Detection of molecular hydrogen quadrupole emission in the Orion nebula. Astrophysical Journal, 207, L129.CrossRef Google Scholar

Green, S. (1974). Quoted in S. I. Chu and A. Dalgarno. Rotational excitation of CH+ by electron impact. Physical Review, A10, 788.Google Scholar

Green, S., Montgomery, J. A. Jr. and Thaddeus, P. (1974). Tentative identification of U93.174 as the molecular ion N2H+. Astrophysical Journal, 193, L89.CrossRef Google Scholar

Herbst, E. and Klemperer, W. (1973). The formation and depletion of molecules in dense interstellar clouds. Astrophysical Journal, 185, 505.CrossRef Google Scholar

Herzberg, G. (1950). Spectra of Diatomic Molecules, 2nd edn. New York, NY: D. van Nostrand.Google Scholar

Hirao, T. and Amano, T. (2003). Laboratory submillimeter-wave detection of D2H+: a new probe into multiple deuteration?Astrophysical Journal, 597, L85.CrossRef Google Scholar

Klemperer, W. (1970). Carrier of the interstellar 89.190 GHz line. Nature, 227, 5264.CrossRef Google Scholar

Teuff, Y., Millar, T. J. and Marwick, A. J. (2000). UMIST database for astrochemistry. Astronomy and Astrophysical Supplement Series, 146, 157. http://www.rate99.co.uk.CrossRef Google Scholar

Lis, D. C., Roueff, E., Gerin, M.et al. (2002). Detection of triply deuterated ammonia in the Barnard 1 cloud. Astrophysical Journal, 571, L55.CrossRef Google Scholar

Mahan, B. (1975). Electronic structure and chemical dynamics. Accounts of Chemical Research, 8, 55.CrossRef Google Scholar

McCall, B. J., Geballe, T. R., Hinkle, K. H.et al. (1999). Observations of H+3 in dense molecular clouds. Astrophysical Journal, 522, 388.Google Scholar

McCall, B. J., Hinkle, K. H., Geballe, T. T.et al. (1998). H+3 in dense and diffuse clouds. Faraday Discussions, 109, 267.Google Scholar

McKellar, A. (1942). Molecular lines from the lowest states of diatomic molecules composed of atoms probably present in interstellar space. Publications of the Dominion Astrophysical Observatory, Victoria B.C., 7, 251.Google Scholar

Muenter, J. S. (1975). Electric dipole moment of carbon monoxide. Journal of Molecular Spectroscopy, 55, 490.CrossRef Google Scholar

Oka, T. (1980). Observation of the infrared spectrum of H+3 in laboratory and space. Physical Review Letters, 45, 531.CrossRef Google Scholar

Oka, T. (1992). The infrared spectrum of H+3 in laboratory and space plasmas. Reviews of Modern Physics, 64, 1141.CrossRef Google Scholar

Peebles, P. J. E. (1993). Principles of Physical Cosmology. Princeton, NJ: Princeton University Press.Google Scholar

Phelps, D. H. and Dalby, F. W. (1966). Experimental determination of the electric dipole moment of the ground electronic state of CH. Physical Review Letters, 16, 3.CrossRef Google Scholar

Rank, D. M., Townes, C. H. and Welch, W. J. (1971). Interstellar molecules and dense clouds. Science, 174, 1083.CrossRef Google Scholar PubMed

Roberts, H., Herbst, E. and Millar, T. J. (2003). Enhanced deuterium fractionation in dense interstellar cores resulting from multiply deuterated H+3. Astrophysical Journal, 591, L41.CrossRef Google Scholar

Scappini, F., Cecchi-Pestellini, C., Smith, H.et al. (2003). Hydrated sulfuric acid in dense molecular clouds. Monthly Notices, Royal Astronomical Society, 341, 657.CrossRef Google Scholar

Solomon, P. M., Downes, D. and Radford, S. (1992). Dense molecular gas and starbursts in ultraluminous galaxies. Astrophysical Journal, 387, L55.CrossRef Google Scholar

Stark, R., Tak, F. F. S. and Dishoeek, E. (1999). Detection of interstellar H2D+ emission. Astrophysical Journal, 521, L67–70.CrossRef Google Scholar

Thaddeus, P., Guélin, M. and Linke, R. A. (1981). Three new “nonterrestrial” molecules. Astrophysical Journal, 246, L41–5.CrossRef Google Scholar

Thompson, R. and Dalby, F. W. (1968). Experimental determination of the dipole moments of the X(2SIGMA+) and B(2SIGMA+) states of the cyanide molecule. Canadian Journal of Physics, 46, 2815.CrossRef Google Scholar

Townes, C. H. and Schawlow, A. L. (1975). Microwave Spectroscopy. New York, NY: Dover.Google Scholar

Turner, B. E. (1974). U93.174 – a new interstellar line with quadrupole hyperfine splitting. Astrophysical Journal, 193, L83.CrossRef Google Scholar

Vastel, C., Phillips, T. G. and Yoshida, H. (2004). Detection of D2H+ in the dense interstellar medium. Astrophysical Journal, 606, L127–30.CrossRef Google Scholar

Walmsley, C. M. (1993). Abundance anomalies in hot and cold molecular clouds. Journal of the Chemical Society Faraday Transactions, 89, 2119.CrossRef Google Scholar

Woods, R. C., Dixon, T. A., Saykally, R. J.et al. (1975). Laboratory microwave spectrum of HCO+. Physical Review Letters, 35, 1269.CrossRef Google Scholar

Book contents

17 - Fine-tuning and interstellar chemistry

Summary

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive