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  • Journal article
    Blyth AJ, Watson JS, 2009,

    Thermochemolysis of organic matter preserved in stalagmites: a preliminary study

    , Organic Geochemistry, Vol: 40, Pages: 1029-1031

    The analysis of organic matter (OM) preserved in stalagmites is a growing field, but there have been few studies of biomarker compounds such as lignin phenols that are widely used in other palaeoenvironmental contexts. Here we present a preliminary qualitative study of the OM in six stalagmite samples from contrasting environments, using thermochemolysis in the presence of tetramethylammonium hydroxide (TMAH). The results indicate that a wide variety of products is preserved, including several potential lignin-derived compounds, but also that further research is needed to maximise compound recovery and allow the analysis of dissolved OM preserved in stalagmites to reach its full potential.

  • Journal article
    Nicoara S, Tonidandel L, Traldi P, Watson J, Morgan G, Popa Oet al., 2009,

    Determining the levels of volatile organic pollutants in urban air using a gas chromatography-mass spectrometry method

    , Journal of Environmental and Public Health

    The paper presents the application of a method based on coupled gas chromatography-mass spectrometry, using an isotopically labelled internal standard for the quantitative analysis of benzene (B), toluene (T), ethyl benzene (E), and o-, m-, p-xylenes (X). Their atmospheric concentrations were determined based on short-term sampling, in different sites of Cluj-Napoca, a highly populated urban centre in N-W Romania, with numerous and diversified road vehicles with internal combustion engines. The method is relatively inexpensive and simple and shows good precision and linearity in the ranges of 7–60 μg/m3 (B), 13–90 μg/m3 (T), 7–50 μg/m3 (E), 10–70 μg/m3 (X-m,p), and 20–130 μg/m3 (X-o). The limits of quantitation/detection of the method LOQ/LOD are of 10/5 μg/m3 (Xo), 5/3 μg/m3 (B, E, X-m,p), and of 3/1 μg/m3 (T), respectively.

  • Book chapter
    Bougeard CMM, Janmohamed IHS, Goslan EH, Jefferson B, Watson JS, Morgan GH, Parsons SAet al., 2008,

    Parameters affecting haloacetic acid and trihalomethane concentrations in treated UK drinking waters

    , Occurrence, Formation, Health Effects, and Control of Disinfection By-Products in Drinking Water, Editors: Karanfil, Krasner, Westerhoff, Xie, Publisher: Oxford University Press, USA, Pages: 95-108, ISBN: 9780841269507
  • Conference paper
    Needham AW, Smith CL, Sephton MA, Martins Z, Russell SSet al., 2008,

    Gamma irradiation effects on martian analogues

    , Workshop on Antarctic Meteorites - Search, Recovery, and Classification, Publisher: METEORITICAL SOC, Pages: A114-A114, ISSN: 1086-9379
  • Conference paper
    Martins Z, Alexander CMO, Orzechowska GE, Elsila JE, Glavin DP, Dworkin JP, Sephton MA, Ehrenfreund Pet al., 2008,

    Amino acid composition of primitive CR2 chondrites

    , Workshop on Antarctic Meteorites - Search, Recovery, and Classification, Publisher: METEORITICAL SOC, Pages: A90-A90, ISSN: 1086-9379
  • Journal article
    Montgomery W, Crowhurst JC, Zaug JM, Jeanloz Ret al., 2008,

    The chemistry of cyanuric acid (H<sub>3</sub>C<sub>3</sub>N<sub>3</sub>O<sub>3</sub>) under high pressure and high temperature

    , JOURNAL OF PHYSICAL CHEMISTRY B, Vol: 112, Pages: 2644-2648, ISSN: 1520-6106
  • Journal article
    Sephton MA, Botta O, 2008,

    Extraterrestrial organic matter and the detection of Life

    , SPACE SCI REV, Vol: 135, Pages: 25-35, ISSN: 1572-9672

    A fundamental goal of a number of forthcoming space missions is the detection and characterization of organic matter on planetary surfaces. Successful interpretation of data generated by in situ experiments will require discrimination between abiogenic and biogenic organic compounds. Carbon-rich meteorites provide scientists with examples of authentic extraterrestrial organic matter generated in the absence of life. Outcomes of meteorite studies include clues to protocols that will enable the unequivocal identification of organic matter derived from life. In this chapter we summarize the diagnostic abiogenic features of key compound classes involved in life detection and discuss their implications for analytical instruments destined to fly on future spacecraft missions.

  • Journal article
    Bada JL, Ehrenfreund P, Grunthaner F, Blaney D, Coleman M, Farrington A, Yen A, Mathies R, Amudson R, Quinn R, Zent A, Ride S, Barron L, Clark B, Glavin D, Hofmann B, Josset JL, Rettberg P, Robert F, Sephton Met al., 2008,

    Urey: Mars organic and oxidant detector

    , SPACE SCI REV, Vol: 135, Pages: 269-279, ISSN: 1572-9672

    One of the fundamental challenges facing the scientific community as we enter this new century of Mars research is to understand, in a rigorous manner, the biotic potential both past and present of this outermost terrestrial-like planet in our solar system. Urey: Mars Organic and Oxidant Detector has been selected for the Pasteur payload of the European Space Agency’s (ESA’s) ExoMars rover mission and is considered a fundamental instrument to achieve the mission’s scientific objectives. The instrument is named Urey in recognition of Harold Clayton Urey’s seminal contributions to cosmochemistry, geochemistry, and the study of the origin of life. The overall goal of Urey is to search for organic compounds directly in the regolith of Mars and to assess their origin. Urey will perform a groundbreaking investigation of the Martian environment that will involve searching for organic compounds indicative of life and prebiotic chemistry at a sensitivity many orders of magnitude greater than Viking or other in situ organic detection systems. Urey will perform the first in situ search for key classes of organic molecules using state-of-the-art analytical methods that provide part-per-trillion sensitivity. It will ascertain whether any of these molecules are abiotic or biotic in origin and will evaluate the survival potential of organic compounds in the environment using state-of-the-art chemoresistor oxidant sensors.

  • Conference paper
    Jiao D, Perry RS, Engel MH, Sephton MAet al., 2008,

    Biomarker indicators of bacterial activity and organic fluxes during end Triassic mass extinction event (art. no. 709709)

    , Conference on Instruments, Methods, and Missions for Astrobiology XI, Publisher: The International Society for Optical Engineering, Pages: 1-12
  • Book chapter
    Gounell M, Morbidelli A, Bland PA, Spurny P, Young ED, Sephton MAet al., 2008,

    Meteorites from the Outer Solar System?

    , The Solar System Beyond Neptune, Editors: Baruchi MA, Boenhardt H, Cruikshank DP, Morbidelli A, Barucci MA, Boehnhardt H, Cruikshank DP, Morbidelli A, Tucson, Arizona, Publisher: The University of Arizona Press, Pages: 525-541, ISBN: 978-0-8165-2755-7
  • Journal article
    Sephton MA, Carvell RP, Sims MR, Dannatt Let al., 2008,

    The UK’s search for life on Mars

    , ASTRON GEOPHYS, Vol: 49, Pages: 33-36, ISSN: 1366-8781
  • Journal article
    Perry RS, Sephton MA, 2008,

    Solving the mystery of desert varnish with microscopy

    , In Focus, Vol: 11, Pages: 62-76, ISSN: 1750-4740

    In areas such as Death Valley California whole mountains shimmer as light is reflected from widespread coatings of black opalescent desert varnish (Figure 1). Similar desert varnishes have been found on all continents, in locations such as the Gobi (Figure 2), Sonoran, Mojave, Namibian (Figure 3), Victorian and Atacama Deserts. These dark, lustrous coatings have attracted the interest of scientists for centuries. In 1852, the German naturalist and explorer Alexander Humboldt observed desert varnish on a transatlantic expedition and questioned how this enigmatic feature may have formed. His contemporary, Charles Darwin also engaged in the search for explanations for this unusual rock coating and, in 1871, attempted to satisfy his interest by performing chemical analyses. To date many other noteworthy scientists have examined desert varnish and have commented on its bulk chemistry, the arid conditions in which it forms in and the concentration of manganese that makes it opaque and causes it to be black.

  • Journal article
    Preston LJ, Benedix GK, Genge MJ, Sephton MAet al., 2008,

    A multidisciplinary study of silica sinter deposits with applications to silica identification and detection of fossil life on Mars

    , Icarus, Vol: 198, Pages: 331-350, ISSN: 0019-1035

    Surface features observed on Mars and evidence from martian meteorites both suggest that hydrothermal systems have operated in the crust of the planet. Hydrothermal systems are a potential habitat for living organisms and identifying these on Mars is, therefore, important in the search for life beyond the Earth. One of the surface expressions of hydrothermal systems on Earth are silica sinters, deposited during the cooling of hydrothermal solutions. In this paper we present analyses of the mineralogy, textures, chemistry and organic chemistry of silica sinters from two very different geothermal provinces, Waiotapu, New Zealand and Haukadalur, Iceland, in order to determine common features by which silica sinters can be identified. Infrared reflectance spectroscopy was utilised in combination with textural studies to evaluate the mineralogy of sinter deposits in terms of the abundances of different polymorphs of SiO2. Concentrations of organic molecules, principally lipids, within regions of the sinters in which there is textural evidence for micro-organisms were identified in the infrared spectral data and their presence was confirmed using gas chromatography mass spectroscopy. The results of this study indicate that reflectance spectra in the wavelength region from 2.5 to 14 μm, when calibrated against natural terrestrial analogues, can be used to identify silica sinters, as well as the possible presence of recent microbial communities on Mars.

  • Journal article
    Aubrey AD, Chalmers JH, Bada JL, Grunthaner FJ, Amashukeli X, Willis P, Skelley AM, Mathies RA, Quinn RC, Zent AP, Ehrenfreund P, Amundson R, Glavin DP, Botta O, Barron L, Blaney DL, Clark BC, Coleman M, Hofmann BA, Josset JL, Rettberg P, Ride S, Robert F, Sephton MA, Yen Aet al., 2008,

    The Urey Instrument: An Advanced In Situ Organic and Oxidant Detector for Mars Exploration

    , Astrobiology, Vol: 8, Pages: 583-595, ISSN: 1531-1074

    The Urey organic and oxidant detector consists of a suite of instruments designed to search for several classes of organic molecules in the martian regolith and ascertain whether these compounds were produced by biotic or abiotic processes using chirality measurements. These experiments will also determine the chemical stability of organic molecules within the host regolith based on the presence and chemical reactivity of surface and atmospheric oxidants. Urey has been selected for the Pasteur payload on the European Space Agency's (ESA's) upcoming 2013 ExoMars rover mission. The diverse and effective capabilities of Urey make it an integral part of the payload and will help to achieve a large portion of the mission's primary scientific objective: “to search for signs of past and present life on Mars.” This instrument is named in honor of Harold Urey for his seminal contributions to the fields of cosmochemistry and the origin of life.

  • Journal article
    Martins Z, Botta O, Fogel ML, Sephton MA, Glavin DP, Watson JS, Dworkin JP, Schwartz AW, Ehrenfreund Pet al., 2008,

    Extraterrestrial nucleobases in the Murchison meteorite

    , EARTH PLAN SCI LETT, Vol: 270, Pages: 130-136, ISSN: 0012-821X

    Carbon-rich meteorites, carbonaceous chondrites, contain many biologically relevant organic molecules and delivered prebiotic material to the young Earth. We present compound-specific carbon isotope data indicating that measured purine and pyrimidine compounds are indigenous components of the Murchison meteorite. Carbon isotope ratios for uracil and xanthine of δ13C=+44.5‰ and +37.7‰, respectively, indicate a non-terrestrial origin for these compounds. These new results demonstrate that organic compounds, which are components of the genetic code in modern biochemistry, were already present in the early solar system and may have played a key role in life's origin.

  • Journal article
    Lomax BH, Fraser WT, Sephton MA, Callaghan TV, Self S, Harfoot M, Pyle JA, Wellman CH, Beerling DJet al., 2008,

    Plant spore walls as a record of long-term changes in ultraviolet-B radiation

    , Nature Geoscience, Vol: 1, Pages: 592-596, ISSN: 1752-0894

    Stratospheric ozone screens the Earth's surface from harmful ultraviolet-B radiation. Concentrations of stratospheric ozone are governed by a variety of natural and anthropogenic factors, including solar cycles1, volcanic aerosols2, ozone-depleting substances3 and climate change4. However, assessing this variability before instrumental records has proved difficult owing to the lack of a well-constrained proxy5. Here, we use microspectroscopy to analyse the chemical composition of herbarium samples of clubmoss (Lycophyta) spores originating from high- and low-latitude localities, where they were exposed to different ultraviolet-B histories. We show that the concentration of two ultraviolet-B-absorbing compounds in the walls of high-northern- and southern-latitude spores is strongly regulated by historical variations in ultraviolet-B radiation. Conversely, we find little change in the concentration of these compounds in spores originating from tropical Ecuador, where ultraviolet levels have remained relatively stable. Using spores from Greenland, we reconstruct past (1907–1993) changes in ozone concentration and ultraviolet-B flux; we reveal strong similarities between spore-wall reconstructions, and independent instrumental records6 and model results7. Our findings suggest that ultraviolet-B-absorbing compounds in plant spore walls have the potential to act as a proxy for past changes in terrestrial ultraviolet-B radiation and stratospheric ozone. The chemical signature of plant spore walls in herbaria, and possibly also in sedimentary and ice-core archives, may therefore prove valuable for reconstructing past variations in stratospheric ozone and their connections with changes in solar radiation and climate.

  • Journal article
    Carvell RP, Sims MR, Sephton MA, Dannatt Let al., 2008,

    The Search for Life on Mars

    , Science in Parliament, Vol: 65, Pages: 12-13, ISSN: 0263-6271
  • Journal article
    Marlow JJ, Martins Z, Sephton MA, 2008,

    Mars on Earth: soil analogues for future Mars missions

    , ASTRON GEOPHYS, Vol: 49, Pages: 20-23, ISSN: 1366-8781

    Preparations for missions to Mars are a major concern for scientists. Predicting how equipment and experiments will perform on the planet is difficult because tests are restricted to Earth. Mars soil analogues are being used to solve this problem. These terrestrial materials are chemically and physically similar to martian soils and, because they contain unusual minerals and trace amounts of organic matter, are scientifically interesting in their own right. However,no current analogue is appropriate for all necessary tests. Here we describe Mars soil analogues, identify limitations and suggest the need for new Mars simulants.

  • Journal article
    Marlow JJ, Martins Z, Sephton MA, 2008,

    Mars on Earth: soil analogues for future Mars missions

    , Astronomy & Geophysics, Vol: 49, Pages: 2.2-2.5
  • Journal article
    Sephton MA, Meredith W, Sun C-G, Snape CEet al., 2007,

    Biomedical and forensic applications of combined catalytic hydrogenation-stable isotope ratio analysis

    , Analytical Chemistry Insights, Vol: 2, Pages: 37-42, ISSN: 1177-3901

    Studies of biological molecules such as fatty acids and the steroid hormones have the potential to benefit enormously from stable carbon isotope ratio measurements of individual molecules. In their natural form, however, the body’s molecules interact too readily with laboratory equipment designed to separate them for accurate measurements to be made.Some methods overcome this problem by adding carbon to the target molecule, but this can irreversibly overprint the carbon source ‘signal’. Hydropyrolysis is a newly-applied catalytic technique that delicately strips molecules of their functional groups but retains their carbon skeletons and stereochemistries intact, allowing precise determination of the carbon source. By solving analytical problems, the new technique is increasing the ability of scientists to pinpoint molecular indicators of disease, elucidate metabolic pathways and recognise administered substances in forensic investigations.

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