Utilization of Spectral Gamma Ray Logs to Ascertain Stratigraphic Surfaces in Carbonate Reservoir and Integration with Seismic Interpretation: An Integrated Case Study from Eocene-Oligocene Carbonate Reservoirs, D31 Cluster, Mumbai Offshore Basin, India

Manabesh Chowdhury, Arun Babu Nalamara, V. Sunder, Pankaj Kumar, P. Mohapatra, S. Roy
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Abstract

D31 cluster is located in the prolific Mumbai Offshore Basin, Western part of India. B-192Afield is part of this cluster, where Bassein (Middle Eocene),Mukta and Panvel (Early Oligocene)Formations are the main reservoirs. The reservoirs are complex in terms of reservoir heterogeneity. They were deposited in a shallow marine carbonate platform.Sea level fluctuations andchange in depositional environment impacted the porosity development. The main objective of this study was to integrate spectral gamma ray signatures with seismic interpretation for demarcating significant stratigraphic surfaces and differentiating depositional environments for robust reservoir characterization. Regionally, Bassein Formation (Middle Eocene) is characterized by thick foraminiferal and algal wackestone, packstone and occasional grainstone facies.The Mukta Formation (Early Oligocene),which unconformably overlies the Bassein Formation, is characterized by presence of fossiliferous limestone with shale intercalations. In the present study, data from four exploration wells data have been analyzed, where spectral gamma ray log patterns in carbonate reservoirs appear to have a distinctive relationship to depositional facies and stratigraphic surfaces in the Bassein and Mukta Formations. Different cross plots have also been utilized for analyzing the depositional conditions (i.e. oxic or anoxic).Later, the spectral log interpretations have been integrated with seismic interpretation. This study is part of a larger effort for reservoir characterization, as a basis for seismic interpretation and integrated reservoir modelling. The spectral gamma ray signatures demarcated significant stratigraphic surfaces. In BasseinFormation, three different units have been marked as Upper, Middle and Lower Bassein. The major lithological boundary between the Bassein and Mukta Formation is also well demarcated with spectral GR signature. The carbonate strata of Bassein & Mukta Formation have also been subdivided with U-Th-K abundance.The "Low Th-Low U" units indicative of pure carbonate and deposition in oxidizing environment whereas "Low Th-High U"is indicative ofreducing environment, which gave a relative sea level fluctuation in the area.The major stratigraphic boundaries identified from these spectral GR logs has been incorporated in the seismicinterpretation and used for regional seismic mapping.As porosity development is governed by thesea level fluctuations,this study also gave an indication of the possibility of porous zonein the reservoir section. These results can be useful as a basis for applying spectral GR signature as a tool for stratigraphic interpretation in un-cored heterogenous carbonate sections. Along with the petrophysical interpretation, integration of core analysis, biostratigraphy and seismic attribute are critical for detailed carbonate reservoir characterization incorporating depositional environment.This approach can be applied to support commercial development of the complex carbonate reservoirs.
利用伽马谱测井确定碳酸盐岩储层地层面并与地震解释相结合——以印度孟买海上盆地D31群始新统-渐新统碳酸盐岩储层为例
D31集群位于印度西部高产的孟买海上盆地。b -192油田属于该组,其中Bassein组(中始新世)、Mukta组和Panvel组(早渐新世)是主要储层。储层非均质性复杂。它们沉积于浅海碳酸盐台地。海平面的起伏和沉积环境的变化影响了孔隙度的发育。本研究的主要目的是将伽马射线谱特征与地震解释相结合,以划分重要的地层表面,并区分沉积环境,从而实现可靠的储层表征。从区域上看,中始新世Bassein组发育厚有孔虫岩相、藻屑岩相、包岩相和偶有颗粒岩相。穆塔组(早渐新世)不整合覆盖在巴盛组之上,其特征是化石灰岩和页岩夹层。在本研究中,对4口探井的数据进行了分析,发现在Bassein组和Mukta组中,碳酸盐岩储层的伽马谱测井模式似乎与沉积相和地层表面有独特的关系。不同的交叉图也被用来分析沉积条件(即缺氧或缺氧)。后来,谱测井解释与地震解释相结合。这项研究是储层描述的一部分,是地震解释和综合储层建模的基础。能谱伽马射线特征划分了重要的地层面。在BasseinFormation中,三个不同的单元被标记为上、中、下Bassein。用光谱GR信号也很好地划分了Bassein组和Mukta组的主要岩性界线。根据U-Th-K丰度对Bassein & Mukta组碳酸盐岩地层进行了细分。“低th -低U”单元表明纯碳酸盐和氧化环境沉积,“低th -高U”单元表明还原环境,这导致了该地区的相对海平面波动。从这些光谱GR测井中识别的主要地层边界已被纳入地震解释,并用于区域地震填图。由于孔隙度的发育受海平面波动的控制,因此本研究还提示了储层剖面存在多孔带的可能性。这些结果可为在非岩心非均质碳酸盐岩剖面中应用谱GR信号作为地层解释工具奠定基础。除了岩石物理解释外,岩心分析、生物地层学和地震属性的整合对于结合沉积环境进行详细的碳酸盐岩储层表征至关重要。该方法可应用于复杂碳酸盐岩储层的商业开发。
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