Thermal maturity and burial history modelling of shale is enhanced by use of Arrhenius time-temperature index and memetic optimizer

David A. Wood

doi:10.1016/j.petlm.2017.10.004

Petroleum ›› 2018, Vol. 4 ›› Issue (1) :25 -42. DOI: 10.1016/j.petlm.2017.10.004

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Thermal maturity and burial history modelling of shale is enhanced by use of Arrhenius time-temperature index and memetic optimizer

David A. Wood

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Abstract

Thermal maturity indices and modelling based on Arrhenius-equation reaction kinetics have played an important role in oil and gas exploration and provided petroleum generation insight for many kerogen-rich source rocks. Debate continues concerning how best to integrate the Arrhenius equation and which activation energies (E) and frequency factors (A) values to apply. A case is made for the strong theoretical basis and practical advantages of the time-temperature index (∑TTI_ARR) method, first published in 1998, using a single, carefully selected E-A set (E = 218 kJ/mol (52.1 kcal/mol); A = 5.45E+26/my) from the well-established A-E trend for published kerogen kinetics. An updated correlation between ∑TTI_ARR and vitrinite reflectance (Ro) is provided in which the ∑TTI_ARR scale spans some 18 orders of magnitude. The method is readily calculated in spreadsheets and can be further enhanced by visual basic for application code to provide optimization. Optimization is useful for identifying possible geothermal gradients and erosion intervals covering multiple burial intervals that can match calculated thermal maturities with measured Ro data. A memetic optimizer with firefly and dynamic local search memes is described that flexibly conducts exploration and exploitation of the feasible, multi-dimensional, thermal history solution space to find high-performing solutions to complex burial and thermal histories. A complex deep burial history example, with several periods of uplift and erosion and fluctuating heat flow is used to demonstrate what can be achieved with the memetic optimizer. By carefully layering in constraints to the models specific insights to episodes in their thermal history can be exposed, leading to better characterization of the timing of petroleum generation. The objective function found to be most effective for this type of optimization is the mean square error (MSE) of multiple burial intervals for the difference between calculated and measure Ro. The sensitively-scaled ∑TTI_ARR methodology, coupled with the memetic optimizer, is well suited for rapidly conducting basin-wide thermal maturity modelling involving multiple pseudo-wells to provide thermal maturity analysis at fine degrees of granularity.

Keywords

Arrhenius time-temperature index ∑TTI_ARR / Petroleum thermal maturation modelling / Thermal maturity optimization / Geothermal gradient constraints / Memetic firefly optimizer / Burial history phases of erosion

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David A. Wood. Thermal maturity and burial history modelling of shale is enhanced by use of Arrhenius time-temperature index and memetic optimizer. Petroleum, 2018, 4(1): 25-42 DOI:10.1016/j.petlm.2017.10.004

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References

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[1]	N.V. Lopatin, Temperature and geologic time as factors in coalification (in Russian). Akademiya Nauk SSSR Izvestiya, Seriya Geol. 3 (1971) 95-106.

[2]	A. Hood, C.C.M. Gutjahr, R.L. Heacock, Organic metamorphism and the generation of petroleum, AAPG Bull. 59 (1975) 986-996.

[3]	B.P. Tissot, J. Espitalie, L’evolution thermique de la matiere organique des sediments: applications d’une simulation mathematizue, Rev. l’Institut Français Pet. 30 (1975) 743-778.

[4]	D.W. Waples,Time and temperature in petroleum generation and application of Lopatin's technique to petroleum exploration, Am. Assoc. Petroleum Geol. Bull. 64 (1980) 916-926.

[5]	I. Lerche, R.E. Yarzab, G.G. Kendall,Determination of paleoheat flux from vitrinite reflectance data, Am. Assoc. Petroleum Geol. Bull. 68 (1984) 1704-1717.

[6]	M.D. Lewan, Evaluation of petroleum generation by hydrous pyrolysis experimentation, Philos. Trans. R. Soc. Lond. Ser. A 315 (1985) 123-134.

[7]	D.A. Wood,Relationships between thermal maturity indices of Arrhenius and lopatin methods: implications for petroleum exploration (Feb) 72, Am. Assoc. Petroleum Geol. Bull. (1988) 115-135.

[8]	D.A. Wood, Thermal Maturation Modeling Using Spreadsheets, Geobyte (Feb), 1990, pp. 56-61.

[9]	S. Larter, Chemical modelling of vitrinite reflectance evolution, Geol. Rundsch. 78 (1989) 349-359.

[10]	J.J. Sweeney, A.K. Burnham,Evaluation of a simple model of vitrinite reflectance based on chemical kinetics, Am. Assoc. Petroleum Geol. Bull. 74 (10) (1990) 1559-1570.

[11]	S.B. Nielsen, T. Barth, Vitrinite reflectance: comments on “A chemical kinetic model of vitrinite maturation and reflectance” by Alan K. Burnham and Jerry J. Sweeney, Geochimica Cosmochimica Acta 55 (1991) 639-641.

[12]	V. Dieckmann, Modelling petroleum formation from heterogeneous source rocks: the influence of frequency factors on activation energy distribution and geological prediction, Mar. Petroleum Geol. 22 (2005) 375-390.

[13]	M.D. Lewan, Experiments on the role of water in petroleum formation, Geochimica Cosmochimica Acta 61 (17) (1997) 3691-3723.

[14]	W.-L. Huang, Experimental study of vitrinite maturation: effects of temperature, time, pressure, water, and hydrogen index, Org. Geochem. 24 (2) (1996) 233-241.

[15]	S. He, M. Middleton, Heat flow and thermal maturity modelling in the northern carnarvon basin, north west shelf, Australia, Mar. Petroleum Geol. 19 (2002) 1073-1088.

[16]	J.A. Nunn, Burial and Thermal History of the haynesville shale: implications for overpressure, gas generation, and natural hydrofracture, Gulf Coast Assoc. Geol. Soc. (GCAGS) J. (2012) 81-96.

[17]	R. Yang, S. He, T. Li, X. Yang, Q. Hu, Origin of over-pressure in clastic rocks in Yuanba area, northeast Sichuan Basin, China, J. Nat. Gas Sci. Eng. 30 (2016) 90-105.

[18]	R. Yang, S. He, Q. Hu, D. Hu, J. Yi, Geochemical characteristics and origin of natural gas from Wufeng-Longmaxi shales of the Fuling gas field, Sichuan Basin (China), Int. J. Coal Geol. 171 (2017) 1-11.

[19]	A.Y. Mohamed, A.J. Whiteman, S.G. Archer, S.A. Bowden, Thermal modelling of the Melut basin Sudan and South Sudan: implications for hydrocarbon generation and migration, Mar. Petrol. Geol. 77 (2016) 746-762.

[20]	A.S. Pepper, P.J. Corvi, Simple kinetic models of petroleum formation: Part I -Oil and gas generation from kerogen, Mar. Petrol. Geol. 12 (1995) 291-319.

[21]	C. Cornford, Source rocks and hydrocarbons of the north sea, chapter 11,in: K.W. Glennie (Ed.), Petroleum Geology of the North Sea:Basic Concepts and Recent Advances, fourth ed., 2009, pp. 376-462.

[22]	J.G. Stainforth, Practical kinetic modeling of petroleum generation and expulsion, Mar. Petroleum Geol. 26 (2009) 552-572.

[23]

T.T.Y. Ho, R.E. Jensen, S.K. Sahai, R.H. Leadholm, O. Senneseth, Comparative studies of pre-and post-drilling modelled thermal conductivity and maturity data with post-drilling results: implications for basin modelling and hydrocarbon exploration,in: S. J. Duppenbecker, J.E. Iliffe (Basin Modelling:Eds.), Practice and Progress, vol. 141, Geological Society, London, 1998, pp. 187-208. Special Publications.

[24]	P. Ungerer, State of the art of research in kinetic modelling of oil formation and expulsion, Proceedings of the 14th International Meeting on Organic Geochemistry, Paris, France, 18-22 September 1989 (Eds B.Durand and F.Behar, Org. Geochem 16 (1990) 1-25.

[25]	K.E. Peters, A.K. Burnham, C.C. Walters, Petroleum generation kinetics: single versus multiple heating-ramp open-system pyrolysis, Am. Assoc. Petrol. Geol. Bull. 99 (4) (2015) 591-616.

[26]	M.D. Lewan, T.E. Ruble, Comparison of petroleum generation kinetics by isothermal hydrous and nonisothermal open-system pyrolysis, Org. Geochem. 33 (2002) 1457-1475.

[27]	S.B. Nielsen, B. Dahl, Confidence limits on kinetic models of primary cracking and implication for the hydrocarbon generation, Mar. Petrol. Geol. 8 (1991) 483-492.

[28]	S. Arrhenius, Über die Reaktionsgeschwindigkeit bei der Inversion von Rohrzucker durch Säuren, Z Phys. Chem. 4 (1889) 226-248.

[29]	V.M. Gorbachev, A solution of the exponential integral in the non-isothermal kinetics for linear heating, J. Therm. Analysis 8 (1975) 349-350.

[30]	X.-S. Yang, Firefly algorithms for multimodal optimization, in: stochastic algorithms: foundations and applications, SAGA, Lect. Notes Comput. Sci. 5792 (2009) 169-178.

[31]	X.-S. Yang, X. He, Firefly algorithm: recent advances and applications, Int. J. Swarm Intell. 1 (1) (2013) 36-50.

[32]	S. Arora, S. Singh, The firefly optimization algorithm: convergence analysis and parameter selection, Int. J. Comput. Appl. 69 (3) (2013) 48-52.

[33]	S. Arora, S. Singh, Performance research on firefly optimization algorithm with mutation, in: International Conference on Communication, Computing & Systems, 2014, pp. 168-172.

[34]	S.K. Pal, C.S. Raj, A.P. Singh, Comparative study of firefly algorithm and particle swarm optimization for noisy non-linear optimization problems, I.J. Intell. Syst. Appl. 10 (2012) 50-57.

[35]	D.A. Wood, Hybrid cuckoo search optimization algorithms applied to complex wellbore trajectories aided by dynamic, chaos-enhanced, fat-tailed distribution sampling and metaheuristic profiling, J. Nat. Gas Sci. Eng. 34 (2016) 236-252.