TY - JOUR
T1 - Integrated well data and 3d seismic inversion study for reservoir delineation and description
AU - Imran, Qazi Sohail
AU - Siddiqui, Numair Ahmad
AU - Latif, Abdul Halim Abdul
AU - Bashir, Yasir
AU - Ali, Almasgari Abdalsalam Abduh Saeed
AU - Jamil, Muhammad
N1 - Publisher Copyright:
© 2020, Geological Society of Malaysia. All rights reserved.
PY - 2020/11
Y1 - 2020/11
N2 - Offshore petroleum systems are often very complex and subtle because of a variety of depositional environments. Characterizing a reservoir based on conventional seismic and well-log stratigraphic analysis in intricate settings often leads to uncertainties. Drilling risks, as well as associated subsurface uncertainties can be minimized by accurate reservoir delineation. Moreover, a forecast can also be made about production and performance of a reservoir. This study is aimed to design a workflow in reservoir characterization by integrating seismic inversion, petrophysics and rock physics tools. Firstly, to define litho facies, rock physics modeling was carried out through well log analysis separately for each facies. Next, the available subsurface information is incorporated in a Bayesian engine which outputs several simulations of elastic reservoir properties, as well as their probabilities that were used for post-inversion analysis. Vast areal coverage of seismic and sparse vertical well log data was integrated by geostatistical inversion to produce acoustic impedance realizations of high-resolution. Porosity models were built later using the 3D impedance model. Lastly, reservoir bodies were identified and cross plot analysis discriminated the lithology and fluid within the bodies successfully.
AB - Offshore petroleum systems are often very complex and subtle because of a variety of depositional environments. Characterizing a reservoir based on conventional seismic and well-log stratigraphic analysis in intricate settings often leads to uncertainties. Drilling risks, as well as associated subsurface uncertainties can be minimized by accurate reservoir delineation. Moreover, a forecast can also be made about production and performance of a reservoir. This study is aimed to design a workflow in reservoir characterization by integrating seismic inversion, petrophysics and rock physics tools. Firstly, to define litho facies, rock physics modeling was carried out through well log analysis separately for each facies. Next, the available subsurface information is incorporated in a Bayesian engine which outputs several simulations of elastic reservoir properties, as well as their probabilities that were used for post-inversion analysis. Vast areal coverage of seismic and sparse vertical well log data was integrated by geostatistical inversion to produce acoustic impedance realizations of high-resolution. Porosity models were built later using the 3D impedance model. Lastly, reservoir bodies were identified and cross plot analysis discriminated the lithology and fluid within the bodies successfully.
KW - 3D seismic inversion
KW - Petrophysics
KW - Reservoir characterization
KW - Reservoir delineation
KW - Rock physics
KW - Thin-beds
UR - http://www.scopus.com/inward/record.url?scp=85096991289&partnerID=8YFLogxK
U2 - 10.7186/bgsm70202016
DO - 10.7186/bgsm70202016
M3 - Article
AN - SCOPUS:85096991289
SN - 0126-6187
VL - 70
SP - 209
EP - 220
JO - Bulletin of the Geological Society of Malaysia
JF - Bulletin of the Geological Society of Malaysia
ER -