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Volume 11 Issue 1
Mar 2000
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Journal of Earth Science  > 2000  >  11(1): 28-36.
Dameng Liu, Kuili Jin. Contrasting on Hydrocarbon Generation Model and Characteristics of Pyrolysis of Modern Aquatic Plant (Gloeocapsa) vs Marine Animal (Mantis Shrimp). Journal of Earth Science, 2000, 11(1): 28-36.
Citation: Dameng Liu, Kuili Jin. Contrasting on Hydrocarbon Generation Model and Characteristics of Pyrolysis of Modern Aquatic Plant (Gloeocapsa) vs Marine Animal (Mantis Shrimp). Journal of Earth Science, 2000, 11(1): 28-36.
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Contrasting on Hydrocarbon Generation Model and Characteristics of Pyrolysis of Modern Aquatic Plant (Gloeocapsa) vs Marine Animal (Mantis Shrimp)

  • 1.

    Department of Geology and Energy Resources, China University of Geosciences, Beijing 100083

  • 2.

    China University of Mining and Technology, Beijing 100083

Funds:  This paper is supported by the project 211 at China University of Geosciences
  • Received Date: 02 Dec 1999
  • Rev Recd Date: 05 Feb 2000
    Abstract

  • A hydrocarbon model of the modern aquatic plant Gloeocapsa and the aquatic animal mantis shrimp was found in thermal simulating experiment. The results show that the modern aquatic plant Gloeocapsa is characterized by late generation, late termination and a long duration of oil generation, while the aquatic animal mantis shrimp is characterized by early generation, early termination and a short duration of oil generation. The n-alkanes from Gloeocapsa and mantis shrimp are characterized by peak carbon C15-C17. With increasing thermal simulating temperature, the peak carbon changes from C17 to C15, and the odd-even predominance of n-alkanes becomes less clear. The products from Gloeocapsa contain abundant phenanthrene and naphthalene compounds, and even a little retene, while those from mantis shrimp are dominated by naphthalene compounds, and are poor in phenanthrene compounds. Gloeocapsa and mantis shrimp are rich in C27 sterane, relatively rich in tricyclic terpanes (C19-C29) and hopanes (C27-C35), poor in 5α, 14β, 17β sterane, and coprostane does not disappear until 450℃. The tricyclic terpanes in Gloeocapsa are characterized by peak carbon C23 and C23 > C21, and in mantis shrimp by C21 and C21 > C23. The content of pregnanes is very low at low temperature of thermal simulation, while above 360℃, high levels of pregnane series compounds and even degraded C25 and C26 steranes occur in thermal simulation products.

     

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