Lithologic Reservoirs ›› 2026, Vol. 38 ›› Issue (1): 78-88.doi: 10.12108/yxyqc.20260107

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Seismic prediction method for thin sandstone reservoirs in shallow water delta front: A case study of the second member of Jurassic Penglaizhen Formation in Western Sichuan Depression

TIAN Wenzhong1(), QIAO Lin1, YUAN Jian1, LI Xingwen1, XIANG Lei1, WANG Changcheng2(), LU Gang2, LU Xihe2   

  1. 1 No. 1 Gas Production PlantSouthwest Oil & Gas Company, SinopecDeyang 618000, Sichuan, China
    2 College of EnergyChengdu University of TechnologyChengdu 610059, China
  • Received:2025-07-10 Revised:2025-08-29 Online:2026-01-01 Published:2026-01-23
  • Contact: WANG Changcheng E-mail:tianwenzhong1979@163.com;wcc-126@163.com

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Abstract:

By integrating seismic and logging interpretation data, a three-in-one characterization technology system for thin sandstone reservoir of “multi-scale seismic sedimentology analysis-logging constrained wave impe-dance inversion-sand body thickness verification” was established. And through seismic attribute analysis, frequency division RGB fusion, and waveform clustering analysis, the sedimentary microfacies and distribution of channel sand bodies of the second member of Jurassic Penglaizhen Formation in Western Sichuan Depression were cha-racterized. The results show that:(1) The reservoir of the second member of Jurassic Penglaizhen Formation in Western Sichuan Depression is mainly composed of underwater distributary channel sand bodies, with logging response feature of “low gamma box curve”, and seismic response feature of “a strong peak and corresponding strong valley reflection”. The establishment of an isochronous stratigraphic framework and isochronous comparisons of well-seismic consistency can improve the accuracy of stratigraphic interpretation. (2) The sedimentary microfacies of the second member of Penglaizhen Formation in the study area are mainly underwater distributary channels and distributary channel bays. JP33-1 sublayer is compopsed of underwater distributary channel deposits, with two channels developed: a northeast-southwest trending one and an east-west trending one. And the northeast-southwest trending channel is wider in development and greater in thickness, making it a key area for further exploration and development. (3) The underwater distributary channel sand bodies of the second member of Penglaizhen Formation in the study area exhibit the geophysical response characteristic of “medium-low impe-dance”.The integrated characterization technology system for thin sandstone reservoir of “multi-scale seismic sedimentology analysis-logging constrained wave impedance inversion-sand body thickness verification”can improve the accuracy of predicting sand body thickness, with correlation coefficient of 0.886 5 between inversion prediction thickness and logging interpretation thickness. The main channel sand body thickness is large, ranging from 10 to 20 m, and the distributary channel sand body thickness is small, ranging from 5 to 10 m.

Key words: seismic sedimentology, shallow water delta, thin sandstone reservoir, isochronous stratigraphic frame-work, RGB fusion, wave impedance inversion, seismic prediction, Penglaizhen Formation, Jurassic, Western Sichuan Depression

CLC Number: 

  • TE121.3

Fig. 1

Structural location of Western Sichuan Depression (a) and comprehensive stratigraphic column of Jurassic Penglaizhen Formation (b)"

Fig. 2

Comprehensive stratigraphic column of well S in Jurassic Penglaizhen Formation of Western Sichuan Depression"

Fig. 3

Well-seismic calibration (a) , seismic profile (b) and comparison of well-tie sections (c) of the second member of Jurassic Penglaizhen Formation in Western Sichuan Depression"

Fig. 4

Stratigraphic section (a) , spectrum analysis (b) and seismic attribute plan (c) of the second member of Jurassic Penglaizhen Formation in Western Sichuan Depression"

Fig. 5

Peak attributes (a) and valley attributes (b) of JP33-1 sublayer in the second member of Jurassic Penglaizhen Formation of Western Sichuan Depression"

Fig. 6

Frequency division profiles of 30 Hz (a), 45 Hz (b), 60 Hz (c) and RGB fusion maps (d—e) of JP33-1 sublayer in the second member of Jurassic Penglaizhen Formation in Western Sichuan Depression"

Fig. 7

Frequency division peak amplitude attribute of 30 Hz (a), 45 Hz (b), 60 Hz (c) of JP33-1 sublayer in the second member of Jurassic Penglaizhen Formation in Western Sichuan Depression"

Fig. 8

Waveform clustering (a), distribution of sedimentary microfacies (b), and comparison of well-tie facies (c) of JP33-1 sublayer in the second member of Jurassic Penglaizhen Formation in Western Sichuan Depression"

Fig. 9

Characterization technology system for thin sandstone reservoir based on seismic sedimentology- logging constrained wave impedance inversion-sand body thickness verification"

Fig. 10

Wave impedance inversion (a), sand body thickness prediction (b), and correlation between wave impedance inversion and sand body thickness (c) of JP33-1 sublayer in Jurassic Penglaizhen Formation, Western Sichuan Depression"

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