Forensic Fingerprinting of Biomarkers for Oil Spill Characterization and Source Identification
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[1] J. B. Rapp,et al. Ubiquitous tar balls with a california-source signature on the shorelines of prince william sound, alaska. , 1995, Environmental science & technology.
[2] J. Moldowan,et al. Structure and significance of a novel rearranged monoaromatic steroid hydrocarbon in petroleum , 1986 .
[3] B. Dahl,et al. Oil-oil correlation using multivariate techniques , 1986 .
[4] C. Pillinger,et al. Rearranged hopanes in sediments and petroleum , 1991 .
[5] Joseph V. Mullin,et al. Using systematic and comparative analytical data to identify the source of an unknown oil on contaminated birds , 1997 .
[6] P. Boehm,et al. Identification of Hydrocarbon Sources in the Benthic Sediments of Prince William Sound and the Gulf of Alaska Following the Exxon Valdez Oil Spill , 1995 .
[7] E. Roger,et al. Hopenes and hopanes methylated in ring-A; correlation of the hopanoids from extant methylotrophic bacteria with their fossil analogues , 1992 .
[8] H. Nytoft,et al. 17α,21α(H)-hopanes: natural and synthetic , 2001 .
[9] R. Prince,et al. 17.alpha.(H)-21.beta.(H)-hopane as a conserved internal marker for estimating the biodegradation of crude oil. , 1994, Environmental science & technology.
[10] David S. Page,et al. A principal‐component and least‐squares method for allocating polycyclic aromatic hydrocarbons in sediment to multiple sources , 1997 .
[11] M. Fingas,et al. Comparison of oil composition changes due to biodegradation and physical weathering in different oils. , 1998, Journal of chromatography. A.
[12] W. S. Wingert. G.c.-m.s. analysis of diamondoid hydrocarbons in Smackover petroleums , 1992 .
[13] D. Page,et al. Identification of petroleum sources in an area impacted by the Amoco Cadiz oil spill , 1988 .
[14] M. Fingas,et al. Chemical Characterization of Crude Oil Residues from an Arctic Beach by GC/MS and GC/FID. , 1995, Environmental science & technology.
[15] S. Esterby. American Society for Testing and Materials , 2006 .
[16] A. Revill,et al. Applications of biomarkers for identifying sources of natural and pollutant hydrocarbons in the marine environment , 1996 .
[17] P. Carlson,et al. Natural Hydrocarbon Background in Benthic Sediments of Prince William Sound, Alaska: Oil vs Coal , 1999 .
[18] J. D. Connolly,et al. Dictionary of terpenoids , 1991 .
[19] O. Grahl-Nielsen,et al. Oil/oil correlation by aid of chemometrics , 1984 .
[20] R. Kagi,et al. Coastal bitumens from Western Australia—long distance transport by ocean currents , 1992 .
[21] G. Demaison,et al. Source correlation of biodegraded oils , 1984 .
[22] Chunqing Jiang,et al. Bakken/Madison petroleum systems in the Canadian Williston Basin. Part 1: C21–C26 20-n-alkylpregnanes and their triaromatic analogs as indicators for Upper Devonian–Mississippian epicontinental black shale derived oils? , 2001 .
[23] S. Larter,et al. Extended hopanes beyond C40 in crude oils and source rock extracts from the Liaohe Basin, N.E. China , 1996 .
[24] K. Rogers,et al. A geochemical appraisal of oil seeps from the East Coast Basin, New Zealand , 1999 .
[25] Liv-Guri Faksness,et al. Round Robin Study--Oil Spill Identification , 2002 .
[26] C. Boreham,et al. Secular and environmental constraints on the occurrence of dinosterane in sediments , 1992 .
[27] L. López,et al. Biomarker 18α(H)-oleanane: a geochemical tool to assess Venezuelan petroleum systems , 2000 .
[28] M. Fingas,et al. Identification and Linkage of Tarballs from the Coasts of Vancouver Island and Northern California Using GC/MS and Isotopic Techniques , 1998 .
[29] M. Fingas,et al. Study of the 25-Year-Old Nipisi Oil Spill: Persistence of Oil Residues and Comparisons between Surface and Subsurface Sediments , 1998 .
[30] P. Boehm,et al. A Holistic Approach to Hydrocarbon Source Allocation in the Subtidal Sediments of Prince William Sound, Alaska, Embayments , 2002 .
[31] B. Simoneit,et al. Petroleum hydrocarbon fingerprinting and sediment transport assessed by molecular biomarker and multivariate statistical analyses in the Eastern Harbour of Alexandria, Egypt , 1995 .
[32] R. A. Noble,et al. Identification of some bicyclic alkanes in petroleum , 1984 .
[33] Mervin F. Fingas,et al. A literature review of the physics and predictive modelling of oil spill evaporation , 1995 .
[34] R. Heintz,et al. Identification of Exxon Valdez Oil in Sediments and Tissues from Prince William Sound and the Northwestern Gulf of Alaska Based on a PAH Weathering Model , 1997 .
[35] M. Fingas,et al. Effect of nitrogen source on biodegradation of crude oil by a defined bacterial consortium incubated under cold, marine conditions , 1999 .
[36] Keith A. Kvenvolden,et al. Hydrocarbons in recent sediment of the Monterey Bay National Marine Sanctuary , 2002 .
[37] A. Marshall,et al. Petroleomics: the next grand challenge for chemical analysis. , 2004, Accounts of chemical research.
[38] H. Takada,et al. Oil Pollution in the Straits of Malacca, Malaysia: Application of Molecular Markers for Source Identification , 2000 .
[39] Rohmer Michel,et al. The hopanoids, prokaryotic triterpenoids and precursors of ubiquitous molecular fossils , 1992 .
[40] S. Killops,et al. Complex series of pentacyclic triterpanes in a lacustrine sourced oil from Korea Bay Basin , 1991 .
[41] M. Fingas,et al. Characterization and identification of the Detroit River mystery oil spill (2002). , 2004, Journal of chromatography. A.
[42] M. Fingas,et al. Identification of Alkylbenzenes and Direct Determination of BTEX and BTEX + C3-Benzenes in Oils by GC/MS , 1995 .
[43] Giorgio Tomasi,et al. Chemical fingerprinting of petroleum biomarkers using time warping and PCA. , 2005, Environmental science & technology.
[44] Merv Fingas,et al. Fractionation of a Light Crude Oil and Identification and Quantitation of Aliphatic, Aromatic, and Biomarker Compounds by GC-FID and GC-MS, Part I , 1994 .
[45] H. Takada,et al. Polycyclic aromatic hydrocarbon (PAHs) and hopanes in stranded tar-balls on the coasts of Peninsular Malaysia: applications of biomarkers for identifying sources of oil pollution. , 2001, Marine pollution bulletin.
[46] J. Moldowan,et al. Use of biological markers in petroleum exploration , 1986 .
[47] R. Summons,et al. Biomarker composition of some asphaltic coastal bitumens from Tasmania, Australia , 1992 .
[48] A. O. Barakat,et al. Source-dependent biomarker properties of five crude oils from the Gulf of Suez, Egypt , 1997 .
[49] Dc. Usepa. EPA Requirements for Quality Assurance Project Plans , 2001 .
[50] M. Fingas,et al. Study of the effects of weathering on the chemical composition of a light crude oil using GC/MS GC/FID , 1995 .
[51] W. A. Burns,et al. Resolving the origin of the petrogenic hydrocarbon background in Prince William Sound, Alaska. , 2001, Environmental science & technology.
[52] P. Albrecht,et al. Novel rearranged ring C monoaromatic steroid hydrocarbons in sediments and petroleums , 1985 .
[53] Maowen Li,et al. Correlation and migration studies of North Central Sumatra oils , 2002 .
[54] W. A. Burns,et al. The natural petroleum hydrocarbon background in subtidal sediments of prince william sound, Alaska, USA , 1996 .
[55] J. Moldowan,et al. Paleoreconstruction by Biological Markers , 1981 .
[56] J. Volkman,et al. Identification of natural, anthropogenic and petroleum hydrocarbons in aquatic sediments. , 1992, The Science of the total environment.
[57] C. Boreham,et al. Molecular fossils in coastal bitumens from southern Australia: signatures of precursor biota and source rock environments , 1994 .
[58] F. Pu,et al. Characteristics of biomarkers in the Recent sediment from Qinghai Lake, northwest China , 1991 .
[59] C. Jianping,et al. APPLICATION OF SESQUITERPANES TO THE STUDY OF OIL-GAS SOURCE : THE GAS-ROCK CORRELATION IN THE QIONGDONGNAN BASIN , 1991 .
[60] J. B. Rapp,et al. Hydrocarbons in oil residues on beaches of islands of Prince William Sound, Alaska , 1993 .
[61] J. W. Leeuw,et al. A cadinene biopolymer in fossil and extant dammar resins as a source for cadinanes and bicadinanes in crude oils from South East Asia , 1990 .
[62] M. Fingas,et al. Characterization and identification of a "mystery" oil spill from Quebec (1999). , 2001, Journal of chromatography. A.
[63] A. Riva,et al. Recognition of 18β (H)oleanane in several crudes and Tertiary-Upper Cretaceous sediments. Definition of a new maturity parameter , 1988 .
[64] I. Kaplan,et al. Fingerprinting of High Boiling Hydrocarbon Fuels, Asphalts and Lubricants , 2001 .
[65] K. Peters,et al. Diamondoid hydrocarbons as indicators of natural oil cracking , 1999, Nature.
[66] Scott A. Stout,et al. Diamondoid Hydrocarbons—Application in the Chemical Fingerprinting of Natural Gas Condensate and Gasoline , 2004 .
[67] Isaac R. Kaplan,et al. Forensic Environmental Geochemistry: differentiation of fuel-types, their sources and release time , 1997 .
[68] D. McKirdy,et al. Botryococcane in a new class of Australian non-marine crude oils , 1986, Nature.
[69] N. Berkowitz. Fossil Hydrocarbons: Chemistry and Technology , 1997 .
[70] Alan P. Bentz. Oil spill identification , 1976 .
[71] R. Philp,et al. Bicyclic sesquiterpenoids and diterpenoids in Australian crude oils , 1981 .
[72] Robert Alexander,et al. Diamondoid hydrocarbon ratios as indicators of biodegradation in Australian crude oils , 2000 .
[73] Barry K. Lavine,et al. Source identification of underground fuel spills by pattern recognition analysis of high-speed gas chromatograms , 1995 .
[74] P. Boehm,et al. The use of Defensible Analytical Chemical Measurements for Oil Spill Natural Resource Damage Assessment , 1991 .
[75] K. Grice,et al. Macrocyclic-alkanes: a new class of biomarker , 2001 .
[76] D. Waples,et al. Biomarkers for geologists , 1991 .
[77] B. Simoneit,et al. Aliphatic and aromatic hydrocarbons in particulate fallout of alexandria, egypt: sources and implications. , 1995, Environmental science & technology.
[78] S. Brassell,et al. Late cretaceous anoxic events in the Brazilian continental margin , 1989 .
[79] R. Atlas,et al. Hydrocarbon Biodegradation and Oil Spill Bioremediation , 1992 .
[80] Chunqing Jiang,et al. Bakken/Madison petroleum systems in the Canadian Williston Basin. Part 3: geochemical evidence for significant Bakken-derived oils in Madison Group reservoirs , 2002 .
[81] R. Swannell,et al. Field evaluations of marine oil spill bioremediation. , 1996, Microbiological reviews.
[82] Kevin J. McCarthy,et al. Middle Distillate Fuel Fingerprinting Using Drimane-Based Bicyclic Sesquiterpanes , 2005 .
[83] K. J. Mccarthy,et al. A Strategy and Methodology for Defensibly Correlating Spilled Oil to Source Candidates , 2001 .
[84] S. Guoying,et al. A geochemical investigation of crude oils from Eastern Pearl River Mouth Basin, South China Sea , 1993 .
[85] M. Fingas,et al. Characterization and source identification of an unknown spilled oil using fingerprinting techniques by GC-MS and GC-FID , 2000 .
[86] P. Doumenq,et al. Long term evolution of petroleum biomarkers in mangrove soil (Guadeloupe) , 1997 .
[87] R. Rosenbauer,et al. PAH refractory index as a source discriminant of hydrocarbon input from crude oil and coal in Prince William Sound, Alaska , 1999 .
[88] I. Kaplan,et al. Patterns of Chemical Changes During Environmental Alteration of Hydrocarbon Fuels , 1996 .
[89] Gregory S. Douglas,et al. Environmental Stability of Selected Petroleum Hydrocarbon Source and Weathering Ratios , 1996 .
[90] J. Oung,et al. Geochemical characteristics of oils from Taiwan , 1994 .
[91] M. Fingas,et al. Long-term fate and persistence of the spilled metula oil in a marine salt marsh environment degradation of petroleum biomarkers. , 2001, Journal of chromatography. A.
[92] M. C. Kennicutt,et al. Organic geochemistry applied to environmental assessments of Prince William Sound, Alaska, after the Exxon Valdez oil spill—a review , 1996 .
[93] S. Luoma,et al. A record of hydrocarbon input to San Francisco Bay as traced by biomarker profiles in surface sediment and sediment cores , 1999 .
[94] Chun Yang,et al. Characterization, weathering, and application of sesquiterpanes to source identification of spilled lighter petroleum products. , 2005, Environmental science & technology.
[95] M. Fingas,et al. Development of oil hydrocarbon fingerprinting and identification techniques. , 2003, Marine pollution bulletin.
[96] R. Kagi,et al. The biomarker composition of some crude oils from Sumatra , 1994 .
[97] K. Peters,et al. The Biomarker Guide: Interpreting Molecular Fossils in Petroleum and Ancient Sediments , 1992 .
[98] J. Hellou,et al. Petroleum biomarkers as tracers of lubricating oil contamination , 1996 .
[99] S. Lanteri,et al. Principal component analysis application in polycyclic aromatic hydrocarbons "mussel watch" analyses for source identification , 2002 .
[100] Moonkoo Kim,et al. Compositional Changes of Aromatic Steroid Hydrocarbons in Naturally Weathered Oil Residues in the Egyptian Western Desert , 2002 .
[101] K. Gürgey. An attempt to recognise oil populations and potential source rock types in Paleozoic sub- and Mesozoic-Cenozoic supra-salt strata in the southern margin of the Pre-Caspian Basin, Kazakhstan Republic , 2002 .
[102] K. Grice,et al. Macrocyclic alkanes in crude oils from the algaenan of Botryococcus braunii , 2002 .
[103] E. J. Gallegos. Identification of new steranes, terpanes, and branched paraffins in Green River shale by combined capillary gas chromatography and mass spectrometry , 1971 .
[104] W. A. Burns,et al. Application of petroleum hydrocarbon chemical fingerprinting and allocation techniques after the Exxon Valdez oil spill , 1997 .
[105] R. Rosenbauer,et al. Geochemical characterization of tarballs on beaches along the California coast. Part I— Shallow seepage impacting the Santa Barbara Channel Islands, Santa Cruz, Santa Rosa and San Miguel , 2004 .
[106] S. Mudge. Reassessment of the hydrocarbons in Prince William Sound and the Gulf of Alaska: identifying the source using partial least-squares. , 2002, Environmental science & technology.
[107] R. Colwell,et al. Microbial degradation of hydrocarbons in the environment. , 1990, Microbiological reviews.
[108] J. Rullkötter,et al. GC-MS characterisation of C27 and C28 triterpanes in sediments and petroleum , 1983 .
[109] J. Connan,et al. Biodegradation of refractory hydrocarbon biomarkers from petroleum under laboratory conditions , 1991, Nature.
[110] Chunqing Jiang,et al. Bakken/Madison petroleum systems in the Canadian Williston Basin. Part 2: molecular markers diagnostic of Bakken and Lodgepole source rocks , 2001 .
[111] L. Magoon,et al. Alaska North Slope Oil-Rock Correlation Study , 1985 .
[112] M. Fingas,et al. Using Multiple Criteria for Fingerprinting Unknown Oil Samples Having Very Similar Chemical Composition , 2002 .
[113] Effects. Oil in the Sea III: Inputs, Fates, and Effects , 2003 .
[114] Riccardo Leardi,et al. Polycyclic aromatic hydrocarbons assessment in the sediments of the Porto Torres Harbor (Northern Sardinia, Italy) , 2004 .
[115] W. A. Burns,et al. Optimizing detection limits for the analysis of petroleum hydrocarbons in complex environmental samples. , 2004, Environmental science & technology.
[116] Per S. Daling,et al. Improved and Standardized Methodology for Oil Spill Fingerprinting , 2002 .
[117] M. Fingas. The Basics of Oil Spill Cleanup, Second Edition , 2000 .
[118] M. Bjorøy,et al. Biodegradation in South Texas Eocene oils — Effects on aromatics and biomarkers , 1986 .
[119] Zhiguang Song,et al. Geochemistry of petroleum systems in the eastern Pearl River Mouth Basin: evidence for mixed oils , 2003 .
[120] A. O. Barakat,et al. Application of geochemical parameters for classification of crude oils from Egypt into source-related types , 2002 .
[121] Jiamo Fu,et al. Diamondoid hydrocarbon ratios: novel maturity indices for highly mature crude oils , 1996 .
[122] Randolph E. Jordan,et al. Fate and weathering of petroleum spills in the marine environment: A literature review and synopsis , 1980 .
[123] Abdel Rahman Farag Hegazi,et al. Application of a Multimolecular Marker Approach to Fingerprint Petroleum Pollution in the Marine Environment , 1999 .
[124] James G. Speight,et al. Handbook of Petroleum Product Analysis , 2002 .
[125] G. Ourisson,et al. HOPANOIDS. I: GEOHOPANOIDS : THE MOST ABUDANT NATURAL PRODUCTS ON EARTH ? , 1992 .
[126] J. Short,et al. Low-maturity Kulthieth Formation Coal: A Possible Source of Polycyclic Aromatic Hydrocarbons in Benthic Sediment of the Northern Gulf of Alaska , 2002 .
[127] M. Fingas,et al. Development of a standard bacterial consortium for laboratory efficacy testing of commercial freshwater oil spill bioremediation agents , 1998, Journal of Industrial Microbiology and Biotechnology.
[128] M Fingas,et al. Study of 22-Year-Old Arrow Oil Samples Using Biomarker Compounds by GC/MS. , 1994, Environmental science & technology.
[129] C. Walters,et al. The Biomarker Guide , 2004 .
[130] Giorgio Tomasi,et al. Integrated methodology for forensic oil spill identification. , 2004, Environmental science & technology.
[131] J. Volkman,et al. Demethylated hopanes in crude oils and their applications in petroleum geochemistry , 1983 .
[132] R. Prince,et al. Weathering of an Arctic oil spill over 20 years: the BIOS experiment revisited. Baffin Island Oil Spill. , 2002, Marine pollution bulletin.
[133] J. Speight. The Chemistry and Technology of Petroleum , 1980 .
[134] R. Prince,et al. Petroleum spill bioremediation in marine environments. , 1993, Critical reviews in microbiology.
[135] Raphael Idem,et al. Crude Oil Chemistry , 2003 .
[136] J. Pella,et al. Estimate of oil persisting on the beaches of Prince William Sound 12 years after the Exxon Valdez oil spill. , 2004, Environmental science & technology.
[137] J. Moldowan,et al. Applications of steranes, terpanes and monoaromatics to the maturation, migration and source of crude oils , 1978 .
[138] R. Philp. Fossil Fuel Biomarkers: Applications and Spectra , 1985 .