Gas-bearing sands appraisal for Zamzama Gas field in Pakistan through inverted elastic attributes assisted with PNN approximation of petrophysical properties

The Pab Formation of Zamzama block, lying in the Lower Indus Basin of Pakistan, is a prominent gas-producing sand reservoir. The optimized production is limited by water encroachment in producing wells, thus it is required to distinguish the gas-sand facies from the remainder of the wet sands and shales for additional drilling zones. An approach is adopted based on a relation between petrophysical and elastic properties to characterize the prospect locations. Petro-elastic models for the identified facies are generated to discriminate lithologies in their elastic ranges. Several elastic properties, including p-impedance (11,600-12,100 m/s*g/cc), s-impedance (7,000-7,330 m/s*g/cc), and Vp/Vs ratio (1.57-1.62), are calculated from the simultaneous prestack seismic inversion, allowing the identification of gas sands in the field. Furthermore, inverted elastic attributes and well-based lithologies are incorporated into the Bayesian framework to evaluate the probability of gas sands. To better determine reservoir quality, bulk volumes of PHIE and clay are estimated using elastic volumes trained on well logs employing Probabilistic Neural Networking (PNN), which effectively handles heterogeneity effects. The results showed that the channelized gas-sands passing through existing well locations exhibited reduced clay content and maximum effective porosities of 9%, confirming the reservoir's good quality. Such approaches can be widely implemented in producing fields to completely assess litho-facies and achieve maximum production with minimal risk.

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Porosity Distribution and Differentiation of Different Types of Fluids in Reservoir of Sawan Gas Field, Lower Indus Basin, Pakistan

Pakistan Journal of Geology ◽

10.2478/pjg-2019-0004 ◽

2019 ◽

Vol 3 (1) ◽

pp. 28-37

Author(s):

M. Asad ◽

H.U. Rahim

Keyword(s):

Acoustic Impedance ◽

Reservoir Characterization ◽

Three Dimensional ◽

Seismic Inversion ◽

Indus Basin ◽

Gas Field ◽

Porosity Distribution ◽

Lower Indus Basin ◽

Seismic Reservoir ◽

Lower Goru Formation

AbstractThe lower Indus basin is one of the prolific basins in Pakistan in which the C-interval of lower Goru formation act as a reservoir. With the help of petrophysical interpretation production zone is recognized and also porosity is calculated at the reservoir level. Through porosity we are able to calculate Ksat. A model based inversion of 2D seismic inversion was performed to ascertain three dimensional dispersion of acoustic impedance in the investigation zone and we have recognized new areas where porosity distribution is maximum and site which is suitable for new well. Porosity and Acoustic impedance are typically contrarily relative to each other. Presently porosity can be anticipated in seismic reservoir characterization by utilizing acoustic impedance from seismic inversion far from well position.

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Rock Physics modeling; attribute application and seismic inversion study in Miano, Lower Indus Basin of Pakistan

10.1190/nsapc2015-124 ◽

2015 ◽

Author(s):

Shazia Asim* ◽

Peimin Zhu ◽

Tayyab Naseer ◽

Shabeer Ahmed ◽

Farrukh Hussain ◽

...

Keyword(s):

Rock Physics ◽

Seismic Inversion ◽

Indus Basin ◽

Lower Indus Basin ◽

Rock Physics Modeling ◽

Physics Modeling

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Improved gas sand facies classification and enhanced reservoir description based on calibrated rock physics modelling: A case study

Open Geosciences ◽

10.1515/geo-2020-0311 ◽

2021 ◽

Vol 13 (1) ◽

pp. 1476-1493

Author(s):

Urooj Shakir ◽

Aamir Ali ◽

Muhammad Raiees Amjad ◽

Muyyassar Hussain

Keyword(s):

Elastic Properties ◽

Rock Physics ◽

Integrated Approach ◽

Poor Quality ◽

Indus Basin ◽

Petrophysical Properties ◽

Gas Field ◽

Facies Classification ◽

Fluid Saturation ◽

Reservoir Facies

Abstract Rock physics provides a dynamic tool for quantitative analysis by developing the basic relationship between fluid, lithological, and depositional environment of the reservoir. The elastic attributes such as impedance, density, velocity, V p/V s ratio, Mu-rho, and Lambda-rho are crucial parameters to characterize reservoir and non-reservoir facies. Rock physics modelling assists like a bridge to link the elastic properties to petrophysical properties such as porosity, facies distribution, fluid saturation, and clay/shale volume. A robust petro-elastic relationship obtained from rock physics models leads to more precise discrimination of pay and non-pay facies in the sand intervals of the study area. The Paleocene aged Lower Ranikot Formation and Pab sandstone of Cretaceous age are proven reservoirs of the Mehar gas field, Lower Indus Basin. These sands are widely distributed in the southwestern part of the basin and are enormously heterogeneous, which makes it difficult to distinguish facies and fluid content in the reservoir intervals. So, an attempt is made in this paper to separate the reservoir facies from non-reservoir facies by using an integrated approach of the petro-elastic domain in the targeted sand intervals. Furthermore, missing logs (S-sonic and P-sonic) were also synthesized in the wells and missing intervals along with improving the poor quality of the density log by captivating the washouts and other side effects. The calibrated rock physics model shows good consistency between measured and modelled logs. Petro-elastic models were predicted initially using petrophysical properties and incorporated at true reservoir conditions/parameters. Lithofacies were defined based on petrophysical cut-offs. Rock physics modelled elastic properties (Lambda-rho versus Mu-rho, impedance versus V p/V s ratio) were then cross-plotted by keeping lithofacies in the Z-axis. The cross-plots clearly separated and demarcated the litho-fluid classes (wet sand, gas sand, shale, and limestone) with specific orientation/patterns which were randomized in conventional petrophysical analysis.

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Alveolinids from the Lower Indus Basin, Pakistan (Eastern Neo‐Tethys ): Systematic and biostratigraphic implications

Geological Journal ◽

10.1002/gj.4119 ◽

2021 ◽

Author(s):

Maqsood Ur Rahman ◽

Muhammad Hanif ◽

Tao Jiang ◽

Sohail Wahid

Keyword(s):

Indus Basin ◽

Lower Indus Basin

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Reservoir characterization using stochastic seismic inversion in “K” gas field, Bonaparte Basin

10.1063/5.0037688 ◽

2021 ◽

Author(s):

Tri Wicaksono ◽

Abdul Haris ◽

Agus Riyanto ◽

Pradityo Riyadi

Keyword(s):

Reservoir Characterization ◽

Seismic Inversion ◽

Gas Field ◽

Stochastic Seismic Inversion

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Application of geostatistical seismic inversion in reservoir characterization of Sapphire gas field, offshore Nile Delta, Egypt

The Leading Edge ◽

10.1190/tle38060474.1 ◽

2019 ◽

Vol 38 (6) ◽

pp. 474-479

Author(s):

Mohamed G. El-Behiry ◽

Said M. Dahroug ◽

Mohamed Elattar

Keyword(s):

Reservoir Characterization ◽

Nile Delta ◽

Seismic Inversion ◽

Reservoir Modeling ◽

Connectivity Analysis ◽

Gas Field ◽

Geostatistical Inversion ◽

Well Data ◽

Reservoir Connectivity ◽

Inversion Techniques

Seismic reservoir characterization becomes challenging when reservoir thickness goes beyond the limits of seismic resolution. Geostatistical inversion techniques are being considered to overcome the resolution limitations of conventional inversion methods and to provide an intuitive understanding of subsurface uncertainty. Geostatistical inversion was applied on a highly compartmentalized area of Sapphire gas field, offshore Nile Delta, Egypt, with the aim of understanding the distribution of thin sands and their impact on reservoir connectivity. The integration of high-resolution well data with seismic partial-angle-stack volumes into geostatistical inversion has resulted in multiple elastic property realizations at the desired resolution. The multitude of inverted elastic properties are analyzed to improve reservoir characterization and reflect the inversion nonuniqueness. These property realizations are then classified into facies probability cubes and ranked based on pay sand volumes to quantify the volumetric uncertainty in static reservoir modeling. Stochastic connectivity analysis was also applied on facies models to assess the possible connected volumes. Sand connectivity analysis showed that the connected pay sand volume derived from the posterior mean of property realizations, which is analogous to deterministic inversion, is much smaller than the volumes generated by any high-frequency realization. This observation supports the role of thin interbed reservoirs in facilitating connectivity between the main sand units.

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