Baur, F., 2019. Predicting petroleum gravity with basin modeling: New kinetic models. AAPG Bulletin (2019) 103 (8): 1811–1837.
Behar, F., Vandenbroucke, M., Tang, Y., Marquis, F., Espitalie, J., 1997. Thermal cracking of kerogen in open and closed systems: determination of kinetic parameters and stoichiometric coefficients for oil and gas generation. Organic Geochemistry, 26, 321–339. DOI
Braun, R.L., Burnham, A.K., 1992. PMOD: A flexible model of oil and gas generation, cracking, and expulsion. Organic Geochemistry, 19, 161-172.
Childs, C., Sylta, Ø., Moriya, S., Morewood, N., Manzocchi, T., Walsh, J.J., Hermanssen, D., 2009. Calibrating fault seal using a hydrocarbon migration model of the Oseberg Syd area, Viking Graben. Marine and Petroleum Geology, 26, 764–774. DOI
Di Primio, R., Horsfield, B., 2006. From petroleum-type organofacies to hydrocarbon phase prediction. AAPG Bulletin, 90, 1031–1058. DOI
Gradstein, F., Ogg, J.G., Smith, A.G., 2004. A Geologic Time Scale 2004. Cambridge University Press.
Ingram, G.M., Urai, J.L., Naylor, M.A., 1997. Sealing processes and top seal assessment, in: P. Møller-Pedersen and A.G. Koestler (Ed.), Norwegian Petroleum Society Special Publications: Hydrocarbon Seals Importance for Exploration and Production. Elsevier, pp. 165–174.
Nielsen, S.B., Clausen, O.R., McGregor, E., 2015. basin%Ro: A vitrinite reflectance model derived from basin and laboratory data. Basin Research. DOI
Pepper, A.S., Corvi, P.J., 1995. Simple kinetic models of petroleum formation. Part I: oil and gas generation from kerogen. Marine and Petroleum Geology, 12, 291–319. DOI
Ritter, U., Duddy, I.R., Mork, A., Johansen, H., Arne, D.C., 1996. Temperature and uplift history of Bjornoya (Bear Island), Barents Sea. Petroleum Geoscience, 2, 133–144. DOI
Sperrevik, S., Gillespie, P.A., Fisher, Q.J., Halvorsen, T., Knipe, R.J., 2002. Empirical estimation of fault rock properties. Norwegian Petroleum Society Special Publications, 11, 109–125.
Sylta, Ø., 2004a. A probabilistic approach to improved geological knowledge and reduced exploration risks using hydrocarbon migration modelling. Petroleum Geoscience, 10, 187–198. DOI.
Sylta, Ø., 2004b. Hydrocarbon migration modeling and exploration risk: Doctoral thesis, Norwegian University of Science and Technology, Trondheim, Norway.
Sylta, Ø., 2005. On the dynamics of capillary gas trapping: implications for the charging and leakage of gas reservoirs. Geological Society, London, Petroleum Geology Conference Series, 6, 625–631. DOI.
Sylta, Ø., and Krokstad, W, 2003. Estimation of oil and gas column heights in prospects using probabilistic basin modeling methods. Petroleum Geoscience, 9, 243–254. DOI.
Sweeney, J., Burnham, A.K., 1990. Evaluation of a simple model of vitrinite reflectance based on chemical kinetics. AAPG Bulletin, 74, 1559–1570.
Tømmerås, A., Sylta, Ø., Daszinnies, M. C., Mencaroni, D. 2018. Pre- and post-well predictions of oil and gas columns using an iterative Monte Carlo technique with 3D petroleum systems modeling. AAPG Bulletin 2018;102(4) 709-728. DOI
Vandenbroucke, M., Behar, F., Rudkiewicz, J.L., 1999. Kinetic modelling of petroleum formation and cracking: implications from the high pressure/high temperature Elgin Field (UK, North Sea). Organic Geochemistry, 30, 1105–1125. DOI
Vassenden, F., Ø. Sylta, and C. Zwach, 2003. Secondary Migration in a 2D Visual Laboratory Model: First EAGE International Conference on Fault and Top Seals - What do we know and where do we go? Montpellier, France, September 2003, 17 p. DOI.
