Controls of Zeolite Development on Reservoir Porosity from Lower Permian Formations in Shawan and Its Adjacent Areas, Western Junggar Basin

Abstract

The Shawan Sag and its adjacent areas are rich in hydrocarbon resources. Moreover, the genesis and evolution patterns of zeolite cements in the sandy conglomerate reservoirs have resulted in diverse types of reservoir spaces, a complex composition, and significant heterogeneity. To investigate their impact on reservoir quality, this study integrates core observations, thin-section petrography, scanning electron microscopy (SEM), whole-rock X-ray diffraction (XRD), and energy-dispersive spectroscopy (EDS) for macro–micro comparative analysis of zeolite cement types, formation mechanisms, and pore systems in the Lower Permian strata of the Shawan Sag and adjacent areas. Research demonstrates that provenance exerts a control on type and origin of the diagenetic zeolites: In the Shawan Sag, zeolites form through hydration of volcanic glass in tuff, while adjacent areas develop zeolites via albitization of plagioclase derived from andesite. This genetic divergence drives pore differentiation: Zeolite (heulandite and laumontite) evolution in the Sag generates grain-edge fractures through cement volume shrinkage and crystalline water release. In contrast, the adjacent areas exhibit reservoir spaces dominated by dissolution pores, resulting from the dissolution of laumontite and calcite, along with a relatively higher overall rock porosity.

1. Introduction

The Shawan Sag is rich in hydrocarbon resources, which is attributed to the presence of thick source rocks and a favorable configuration of key petroleum system elements, including high-quality seals and well-developed structural traps [1,2,3,4]. Zeolite cements extensively developed in the Shawan Sag and adjacent areas exhibit close genetic links to volcaniclastic reservoirs. The intricate formation mechanisms of sandstones and conglomerates with zeolite cementation contribute to significant reservoir heterogeneity in the study area [5,6,7,8,9,10,11].

Wopfner et al. [12] demonstrated in the Ruhuhu Basin that laumontite forms in pore waters with high pH and low PCO₂, significantly reducing reservoir porosity and permeability through Ca-rich plagioclase replacement during early diagenesis. Kralj et al. [13] revealed that the transformation from heulandite to laumontite in the Smrekovec area markedly decreases rock porosity and permeability. Zeolite-rich reservoirs typically contain intercrystalline pores, pressure-solution fractures, and secondary dissolution pores [14]. Tao et al. [7] through a systematic review of global studies on zeolites in petroliferous basins, concluded that diverse zeolite genetic types critically control reservoir quality. Extensive research has been conducted on zeolite reservoirs in the Junggar Basin. Chaowei et al. [15] proposed that early-diagenetic zeolites fill pores and inhibit compaction, while later organic acid dissolution generates secondary pores, forming irregular dissolution pits and intergranular pores. The transition from early unstable hydrous zeolites (e.g., clinoptilolite, heulandite) to late stable low-hydration zeolites (laumontite) creates intercrystalline pores through dehydration, enhancing deep reservoir properties [16]. Laumontite, with weak cement-grain bonding, commonly develops grain-edge fractures, yielding pore systems including dissolution pores, intercrystalline pores, and fractures [17]. Exploration in the Permian strata of the Shawan Sag and adjacent areas reveals significant pore-type variations impacting hydrocarbon productivity. Previous studies on zeolite genesis in the northwestern Junggar Basin failed to uncover regional genetic differences and their pore impacts. Therefore, this study focuses on zeolite-cemented intervals in the Lower Permian of these areas, aiming to clarify the response relationships between zeolite genetic mechanisms and reservoir pore architectures.

2. Geological Setting

The study area is located in the central depression belt of the northwestern margin of the Junggar Basin, primarily encompassing the Shawan Sag and its adjacent Zhongguai and Chepai uplifts (Figure 1). This region has undergone a complex tectonic evolutionary history and possesses a well-developed stratigraphic sequence, making it a significant hydrocarbon-rich zone within the basin. The Shawan Sag, a second-order tectonic unit within the central depression of the Junggar Basin, has its structural framework constrained by surrounding units: it is bounded by the Zhongguai Uplift and the Western Pen-1 Well Sag to the north, adjacent to the Huomatu anticlinal belt to the south, close to the Chepai Uplift to the west, and abuts the Mosuowan and Monan uplifts to the east [2,3]. It is a typical superimposed petroliferous sag having experienced multiple phases of tectonic activity.

The Chepai Uplift features a large-scale, approximately 70-km-long fault zone exhibiting an arcuate (anti-S-shaped) trend. This zone is a key structure controlling the western boundary of the sag, whose intense thrusting activity has decisively influenced regional sedimentary filling, structural deformation, and hydrocarbon migration and accumulation. The Zhongguai Uplift, a NW-SE trending nasal uplift located north of the Mahu Sag and south of the Shawan Sag, has served as a favorable conduit for long-term hydrocarbon migration. Its axial trend follows the fault east of the Hong-3 well, with local development of broad, gentle nose-like structures. The study area exhibits a complete sedimentary sequence from the Carboniferous to the Cenozoic. The Permian system is the key target interval, buried at depths of approximately 5000–7000 m with a total thickness of about 1700–2200 m [1]. It is subdivided, in ascending order, into the Jiamuhe (P₁j), Fengcheng (P₁f), Xiazijie (P₂x), Lower Wu’erhe (P₂w), and Upper Wu’erhe (P₃w) formations. The Jiamuhe Formation (P₁j), consisting mainly of sandy conglomerate, mudstone, and tuffaceous sandy conglomerate with a thickness of 700–800 m, is the primary reservoir in the adjacent uplift areas. The Fengcheng Formation (P₁f), characterized by gray-green tuffite, tuffaceous sandy conglomerate, and dolomitic mudstone with a thickness of 400–500 m, is a significant source rock and the study’s target horizon within the Shawan Sag [18].

This study focuses on the Lower Permian Fengcheng Formation (P₁f) in the Shawan Sag and the contemporaneous Jiamuhe Formation (P₁j) in the adjacent Zhongguai and Chepai uplifts. During the Permian, the northwestern Zhongguai-Chepai Uplift served as the primary provenance for the Shawan Sag, a major depositional center. Controlled by the fault east of the Hong-3 well and the Hongche fault, fan delta systems sourced from the northwest developed in the proximal Zhongguai and Chepai areas. The sediment source composition differs significantly: the Fengcheng Formation in the Shawan Sag is dominated by tuff rich in volcanic glass, whereas the Jiamuhe Formation in the adjacent uplifts is characterized by andesitic rocks rich in plagioclase. This fundamental contrast in sediment source composition governs the types and genetic mechanisms of subsequent zeolite cements during diagenesis, ultimately leading to significant differentiation in reservoir pore systems.

3. Sampling and Analytical Program

3.1. Sample Sources

A total of 89 core samples (including sandstones, tuffs, and andesites) were collected from approximately 15 boreholes (e.g., st1, st002, zj15, zj14, zj4, cp3, cp10) (

Table A1. Summary of well samples, depths, and analytical methods conducted.

Well	Area	Formation	Depth (m)	Lithology	Number of Thin Sections	Number of XRD	Number of SEM-EDS
sp002	Shawan Sag	Fengcheng Formation (P1f)	4514.27~4517.87	Sandy conglomerate	4
sp002			4689.07~4693.6	Sandy conglomerate	4
sp14			5543.32~5549.06	Sandy conglomerate	2
sp16			4877.7~5087.7	Sandy conglomerate	5
sp2			5555.31~5559.85	conglomerate	3
sp3			4693.3~4698.72	Sandy conglomerate	3		1
sp3			4718.27~4721.7	Sandy conglomerate	3		3
sp4			4354.57	Sandy conglomerate			1
sp5			4658.68~4781.07	Sandy conglomerate	5
st002			5400.15~5407.29	Sandy conglomerate	5		2
st2			5720.71~5725.64	conglomerate	3	3	4
st2			5539.18~5542.78	conglomerate	5	2	6
st2			5495	conglomerate	1
cp24			4600.07~4610.98	Sandy conglomerate	3		2
zj14	Zhongguai Uplift	Jiamuhe Formation (P1j)	4294.89~4302	Sandy conglomerate	13		4
zj141			4335.34~4341.88	Sandy conglomerate	8		2
zj141			4403.3~4410.66	Sandy conglomerate	5		2
zj15			4042.7~4050.2	Sandstone	4		3
zj4			4407.74	Sandy conglomerate	1		1
zj4			4408.3~4413.6	Sandy conglomerate	5		1
zj4			4436.98~4445.37	Sandy conglomerate	10	1	2
zj4			4465.72~4473.91	Sandy conglomerate	3
zj4			4537.52~4543.15	Sandy conglomerate	6	4	1
zj4			4628.39~4634.21	Sandy conglomerate	5	1	2
zj5			3884.11	Sandy conglomerate		1
zj6			4880.45~5597.55	Sandy conglomerate		15
zj7			4000.7~4339.52	Sandy conglomerate		3
zj903x			4726.32~4733.2	Sandy conglomerate			3
cp001	Chepai Uplift	Jiamuhe Formation (P1j)	2331.73~2417.99	Sandy conglomerate		2
cp002			2655.23~2779.13	Sandy conglomerate		2	1
cp004			2962	conglomerate	1
cp005			2851.3~2858.2	Sandy conglomerate	3
cp005			2972.59	Sandy conglomerate	1
cp10			3492.5	Sandy conglomerate		1
cp18			2437.4~2455.8	conglomerate		3
cp19			2772~2777.42	conglomerate	1	1
cp21			2527.43~2538.5	Sandy conglomerate	2	1
cp27			4456.65~4459.17	Sandy conglomerate	2
cp2			2836.63	Sandy conglomerate			1
cp5			4670.99~4673.92	conglomerate	3
cp5			4704.25~4709.18	conglomerate	5
cp5			4732.71~4734.14	conglomerate	1		1

, Figure 1b) penetrating the Lower Permian strata in the Shawan Sag and adjacent Chepai and Zhongguai areas. All samples were provided by the Exploration and Development Research Institute of PetroChina Xinjiang Oilfield Company (Karamay, China).

3.2. Clastic Rock Composition Analysis

Representative rock samples were vacuum-impregnated with blue epoxy resin and polished into thin sections using a BROT thin-section preparation system. A total of 193 thin sections were analyzed under a DMWBA300POL-B polarized light microscope (JEOL Ltd., Tokyo, Japan). Point counting (300–500 points per section) was performed to quantify the volumetric fractions of detrital grains, cements, and pores. The counting interval was set at twice the average grain size to ensure statistical representativeness. Special emphasis was placed on identifying zeolite types (analcime, heulandite, laumontite) and their occurrence modes.

3.3. X-Ray Diffraction (XRD) Analysis

Whole-rock XRD analysis was conducted on 40 samples using an XRD-7000 powder diffractometer (Shimadzu Corporation, Tokyo, Japan), with samples pulverized to 250-mesh (grain size ≤ 58 μm) and prepared as powder pellets; testing parameters included a scanning range of 3–65° 2θ, step size of 0.02°, scanning speed of 2°/min, Cu-Kα radiation (λ = 1.5418 Å), operating voltage of 40 kV, and current of 40 mA, while mineral identification involved matching peaks with the ICDD reference database. Powder samples for whole-rock XRD analysis were collected to represent the average mineral composition of the main lithofacies, primarily serving the purpose of deciphering provenance signatures and bulk rock properties (Figure A1 and Figure A2).

3.4. Scanning Electron Microscopy with Energy-Dispersive Spectroscopy (SEM-EDS)

Field-emission scanning electron microscopy (FE-SEM) analysis was performed using a JSM-7800F instrument (JEOL Ltd., Tokyo, Japan) to characterize zeolite cement morphology, dissolution pore structures, and spatial relationships with associated minerals, coupled with EDS spot analysis on representative zeolite-cemented regions to determine micro-scale major element compositions (e.g., Si/Al ratios, Na/K/Ca contents) for validating zeolite mineral types and transformation processes.

4. Results

4.1. Sediment Composition Differences Between Shawan Sag and Adjacent Areas

Due to proximity to paleo-volcanic provenances and proximal sediment-source settings, the Chepaizi and Zhongguai areas exhibit significantly different provenance-derived sediment compositions compared to the Shawan Sag (Figure 2). Integrated core and thin-section analyses reveal distinct source material compositions: tuff dominates (52.97%) in the Shawan Sag, while the Chepazi and Zhongguai areas yield mainly andesitic fragments at 47.99 and 54.06%, respectively (Figure 2a,

Table A2. Rock composition of samples from the Lower Permian sandy conglomerate reservoirs in the Shawan Sag, Chepaizi area, and Zhongguai Uplift based on point-counting data. “/” denotes low content. QG = quartz gravel; FG = feldspar gravel; TG = tuff gravel; AG = andesite gravel; GG = granite gravel; FELG = felsite gravel; BG = basalt gravel.

Well	Area	Formation	Depth (m)	Gravel Content/%
				QG	FG	TG	AG	GG	FELG	BG
sp002	Shawan Sag	Fengcheng Formation (P1f)	4514.27	2	7	49	23	/	/	/
sp002			4515.42	1	7	53	18	/	/	/
sp002			4516.69	/	5	62	13	/	/	/
sp002			4517.85	/	5	53	20	1	/	/
sp002			4689.07	1	4	58	20	/	/	/
sp002			4690.28	/	4	52	17	/	/	/
sp002			4692.91	1	7	59	10	/	/	/
sp002			4693.6	5	11	43	7	2	/	/
sp14			5543.32	2	4	75	6	/	1	/
sp14			5549.06	/	2	13	62	/	/	/
sp16			5087.7	2	22	38	10	/	3	/
sp16			4877.7	/	/	63	/	/	/	/
sp16			4906.3	/	4	43	19	/	1	/
sp16			4939.4	/	3	56	27	/	/	/
sp16			4976.3	/	3	19	55	/	/	/
sp2			5555.31	1	9	54	7	1	/	/
sp2			5557.13	4	12	45	4	/	/	/
sp2			5559.85	8	13	59	/	2	/	/
sp3			4693.3	4	5	54	37	/	/	/
sp3			4718.27	15	17	41	12	/	/	/
sp3			4695.61	1	8	67	6	/	/	/
sp3			4698.4	1	5	68	6	/	/	/
sp3			4719.14	2	7	50	8	1	/	/
sp3			4721.7	1	13	50	14	/	/	/
sp5			4659.98	/	1	60	21	/	/	/
sp5			4662.28	/	/	63	17	/	/	/
sp5			4664.72	/	2	79	3	/	/	/
sp5			4778.82	/	1	73	2	/	/	/
sp5			4780.9	2	6	64	11	1	/	/
st002			5400.15	/	/	75	2	/	/	/
st002			5404.55	/	1	59	18	2	/	/
st002			5407.29	1	/	77	2	/	/	/
st002			5401.28	/	1	46	31	1	/	/
st002			5404.86	/	/	57	27	1	/	/
st2			5722.5	6	5	68	/	/	/	/
st2			5720.71	8	5	68	/	/	/	/
st2			5541.18	5	4	52	/	10	/	/
st2			5539.18	5	6	51	20	/	/	/
st2			5540.2	/	/	52	24	/	/	/
st2			5495	5	8	70	2	/	/	/
st2			5539.65	/	1	35	43	/	/	/
st2			5541.93	/	2	46	39	/	/	/
st2			5724.21	3	5	56	20	/	/	/
cp24			4600.07	5	6	45	38	/	/	/
cp24			4604.89	10	8	60	15	/	/	/
cp24			4610.98	10	25	50	12	/	/	/
zj14	Zhongguai Uplift	Jiamuhe Formation (P1j)	4294.89	/	/	11	61.1	/	/	1
zj14			4295.49	/	/	17	56.4	/	/	1
zj14			4296.45	2	3	16	52.3	/	/	/
zj14			4296.85	2	2	2	5/.5	/	/	/
zj14			4297	2	2	17	51.5	/	/	/
zj14			4297.12	/	/	8	62.5	/	/	/
zj14			4297.3	/	/	9	58.4	/	/	/
zj14			4297.4	/	1	11	49.1	/	/	/
zj14			4297.66	/	1	13	48.5	/	/	/
zj14			4298.06	/	1	11	49.8	/	/	/
zj14			4298.6	/	2	14	47.6	/	/	/
zj14			4301.16	/	1	16	44.7	/	/	/
zj14			4302	/	2	13	55.5	/	/	/
zj141			4335.34	/	1	5	49.4	/	/	/
zj141			4335.78	/	2	16	44.1	/	/	/
zj141			4338.36	/	2	11	58.4	/	/	/
zj141			4338.94	/	2	1	62.9	/	/	/
zj141			4339.19	/	2	12	58	/	/	/
zj141			4339.54	/	2	5.5	61.2	/	/	/
zj141			4341.36	/	2	1	68	/	/	/
zj141			4341.88	/	3	4	69	/	/	/
zj141			4403.3	/	1.2	7	47	/	/	/
zj141			4406.16	/	2	1	67.3	/	/	/
zj141			4407.73	/	1	9	64	/	/	/
zj141			4409.71	/	1	11	61.3	/	/	8
zj141			4410.66	/	1	5	77.5	/	/	2
zj15			4048.99	9.5	44.7	9	4.6	/	/	/
zj15			4049.68	10.3	46.4	5	3.6	/	/	/
zj15			4049.85	8	46.4	2.1	7	/	/	/
zj15			4050.2	1	48	7	3	/	/	/
zj4			4407.74	1	1	5	54	/	/	/
zj4			4408.3	1	1	6	52	/	/	/
zj4			4410.06	4	5	17	37.2	/	7	2
zj4			4411.16	1	1	4	56.8	/	/	/
zj4			4412.56	1	1	5	51.7	/	/	/
zj4	Zhongguai Uplift	Jiamuhe Formation (P1j)	4537.52	1	2	4	55.7	1	3	/
zj4			4538.53	1	2	3	58.9	1	2	/
zj4			4539.53	7	6	2	48.2	/	2	/
zj4			4540.03	7	6	7	41.3	/	2	/
zj4			4542.15	7	7	6	44.1	/	2	/
zj4			4543.15	8	7	7	42.2	/	1	/
zj4			4628.39	8	7	6	42.3	/	/	/
zj4			4628.82	7	6	5	38	/	1	/
zj4			4633.29	2	1	3	36.5	/	1	/
zj4			4633.61	2	1	/	39.3	/	3	/
zj4			4634.19	2	1	1	39	/	3	/
cp004	Chepai Uplift	Jiamuhe Formation (P1j)	2962	/	2	33	46	/	/	2
cp005			2851.3	1	3	20	61	/	1	/
cp005			2852.83	/	4	22	54	/	/	/
cp005			2858.2	4	5	26	48	/	1	/
cp005			2972.59	1	3	38	48.2	/	/	3
cp19			2777.42	3	3	16	67	1	/	/
cp21			2532.5	2	2	29	43	0.8	/	/
cp21			2538.5	0.8	2.2	29	66	/	/	/
cp27			4456.65	/	2	2	89	/	/	/
cp27			4459.17	/	1	1	96	/	/	/
cp5			4670.99	1	27	18	45	/	2	/
cp5			4671.23	3	1	24	49	/	3	/
cp5			4673.92	3.1	5	18	34	/	5	39
cp5			4704.25	2.7	7	/	50	10	/	/
cp5			4705.52	1	35	15	46	/	/	1
cp5			4705.72	1	20	20	29	/	/	2
cp5			4708.83	1	15	5	40	/	1	3
cp5			4709.18	1.5	15	24	40	9.6	/	/
cp5			4734.14	1.2	15.3	25	57	1	/	1

), with laumontite-filled vesicles in amygdaloidal andesitic clasts observed in cores showing laumontite-filled vesicles. The lithology of the Shawan Sag is dominated by tuff grains rich in volcanic glass; in contrast, the adjacent areas are characterized by andesitic grains containing abundant plagioclase Whole-rock XRD analyses confirm quartz predominates in the Shawan Sag, while plagioclase dominates adjacently (Figure 3,

Table A3. Mineral composition (wt.%) of samples from the Lower Permian sandy conglomerate reservoirs in the Shawan Sag, Chepaizi area, and Zhongguai Uplift based on XRD data. All values are in wt.%. “/” denotes trace amount (<2%). Qz = quartz; Pl = plagioclase; Lmt = laumontite; Kfs = K-feldspar; Cal = calcite; Dol = dolomite; Hem = hematite; Anh = anhydrite; Ank = ankerite; Anl = analcime; Sid = siderite.

Well	Area	Formation	Depth (m)	Qz	Pl	Lmt	Kfs	Cal	Dol	Hem	Anh	Ank	Anl	Sid
st2	Shawan Sag	Fengcheng Formation (P1f)	5539.5	34.61	34.61	9.54	17.9	/	/	/	/	/	/	/
st2			5542.78	29.62	29.62	13.03	5.92	3.55	2.37	9.49	4.74	/	/	/
st2			5724.21	66.78	16.08	0	13.6	/	/	/	/	/	/	/
st2			5724.71	49.79	20.96	13.1	13.1	/	/	/	/	1.31	/	/
st2			5725.64	63.55	23.34	11.67	/	/	/	/	/	/	/	/
zj4	Zhongguai Uplift	Jiamuhe Formation (P1j)	4466.04	10.65	36.22	38.34	5.33	3.20	/	5.33	/	/	/	/
zj4			4541.40	14.29	52.38	21.42	8.33	2.38	/	0.00	/	/	/	/
zj4			4538.2	12.79	31.98	24.52	26.65	3.20	/	0.00	/	/	/	/
zj4			4632.8	24.88	36.77	23.79	10.82	3.24	/	/	/	/	/	/
zj4			4439.14	22.51	54.51	0.00	0.00	0.00	/	3.55	/	/	17.77	/
zj4			4537.67	25.88	44.36	0.00	0.00	0.00	/	0.00	/	/	28.34	/
zj6			4880.45	25.74	33.24	15.01	8.58	15.01	/	0.00	/	/	/	/
zj6			4956.41	28.86	48.84	14.43	/	6.66	/	0.00	/	/	/	/
zj6			5009.28	16.86	34.77	12.64	/	32.67	/	0.00	/	/	/	/
zj6			5242.07	28.67	35.55	19.49	/	13.76	/	0.00	/	/	/	/
zj6			5597.55	25.41	43.42	10.59	7.41	8.47	/	0.00	/	/	/	/
zj6			4874.69	28.60	40.50	16.68	5.96	5.96	/	0.00	/	/	/	/
zj6			4878.55	26.10	45.40	7.94	13.62	3.40	/	0.00	/	/	/	/
zj6			4954.59	41.06	34.02	10.56	4.69	0.00	/	7.04	/	/	/	/
zj6			4955.88	32.80	34.98	12.02	4.37	8.74	/	5.46	/	/	/	/
zj6			4957.22	32.41	40.81	14.40	4.80	6.00	/	0.00	/	/	/	/
zj6			5007.6	25.90	34.92	11.26	7.88	10.14	/	7.88	/	/	/	/
zj6			5009.37	28.72	36.46	9.94	6.63	5.52	/	7.73	/	/	/	/
zj6			5010.2	29.48	40.38	17.47	0.00	4.37	/	4.37	/	/	/	/
zj6			5005.1	16.20	36.71	16.20	5.40	17.28	/	6.48	/	/	/	/
zj6			5013.3	13.25	44.16	14.35	6.62	11.04	/	8.83	/	/	/	/
zj7			4000.7	28.67	41.81	14.33	5.97	4.78	/	3.58	/	/	/	/
zj7			4161.46	27.95	34.93	18.63	6.99	4.66	/	2.33	/	/	/	2.33
zj7			4339.52	28.88	32.81	26.25	6.56	3.94	/	0.00	/	/	/	/
zj5			3884.11	19.15	37.18	24.78	13.52	3.38	/	0.00	/	/	/	/
cp001	Chepai Uplift	Jiamuhe Formation (P1j)	2331.73	50.86	33.91	/	/	/	/	/	/	/	8.48	/
cp001			2417.99	46.33	43.01	/	/	/	/	/	/	/	3.31	/
cp002			2655.23	49.20	43.24	/	/	/	/	/	/	/	/	/
cp002			2779.13	43.55	36.66	/	/	6.87	/	/	/	/	10.31	/
cp10			3492.5	16.97	64.26	/	/	/	/	/	/	/	/	/
cp18			2437.4	26.71	51.08	/	/	18.58	/	/	/	/	/	/
cp18			2455.8	33.78	38.61	/	15.69	10.86	/	/	/	/	/	/
cp18			2455.52	37.71	41.14	4.57	/	11.43	/	/	/	2.29	/	/
cp19			2772	25.66	62.11	/	/	/	/	/	/	3.74	6.75	/
cp21			2527.43	52.39	39.92	/	/	/	/	/	/	/	/	/

).

4.2. Zeolite Types in the Shawan Sag and Adjacent Areas

Zeolite minerals (predominantly laumontite, heulandite, and analcime) are extensively developed in the glutenite reservoirs of the Shawan Sag and adjacent areas, yet exhibit significant differences in crystal morphology, occurrence modes, and abundance (Figure 4 and Figure 5). The zeolite assemblages in the Lower Permian sandy conglomerate reservoirs of the Shawan Sag and adjacent areas were characterized using an integrated approach. Analytical techniques included petrographic thin section analysis, whole-rock XRD, EDS, and SEM. In the Shawan Sag, laumontite is the dominant zeolite, followed by subordinate heulandite and trace analcime. Microscopy reveals laumontite-heulandite intergrowths and iron-stained heulandite coexisting with analcime. In peripheral areas, laumontite remains predominant but heulandite is markedly reduced and analcime is virtually absent. There, laumontite primarily replaces plagioclase in andesitic fragments.

4.2.1. Laumontite Mineralogy

Laumontite (CaAl₂Si₄O₁₂·4H₂O) is a monoclinic hydrous layered aluminosilicate mineral. It typically forms columnar crystals, often occurring as acicular, fibrous, or radial aggregates with significant brittleness that readily fractures under stress (Figure 4c,d,g,h and Figure 5a–g,j–l). Under polarized light microscopy, it appears colorless and transparent in thin sections, displaying first-order gray-white to pale yellow interference colors under parallel extinction. Optical characteristics include a maximum extinction angle of 20–30°, biaxial negative optical character, and low negative relief with refractive indices approximating Canada balsam. Perfect cleavage is observed along one or two directions.

In the Shawan Sag glutenite reservoirs, columnar and intergrown laumontite semi-to-fully cements intergranular pores (Figure 4a,c,d), whereas in adjacent areas, laumontite replaces plagioclase along cleavage and twin planes within feldspar fragments and andesite fragments (Figure 5a–c,j), associated with albitization. Columnar/intergrown laumontite co-occurs with calcite cementing intergranular pores (Figure 5a,g,k,l).

4.2.2. Heulandite Mineralogy

Heulandite ((Ca, Na₂)Al₂Si₇O₁₈·6H₂O), a monoclinic framework silicate mineral, exhibits isomorphous substitution of Ca²⁺ by Na⁺ in its crystal chemical formula. It appears yellowish-brown to brick-red due to iron-staining by volcanic materials (Figure 4b,c). Crystallographically, it develops well-formed subhedral to euhedral crystals showing parallel extinction.

In the Shawan Sag, hydration of volcanic glass within tuff fragments during burial diagenesis releases Na⁺ and Ca²⁺, leading to massive, intergrown bundles and platy heulandite crystals growing perpendicularly along grain edges in a semi-filling mode within intergranular pores (Figure 4b,c,e–h). Microscopically, heulandite coexists with analcime (Figure 4c). Conversely, adjacent areas rarely exhibit tabular or prismatic heulandite fully cementing volcanic rocks, with intercrystalline pores developed between heulandite crystals (Figure 5h).

4.2.3. Analcime Mineralogy

Analcime (NaAlSi₂O₆·H₂O), an isometric framework silicate mineral, typically forms tetragonal trisoctahedrons or irregular equant grains. Under crossed-polarized light, it displays anomalous interference colors, while appearing colorless and transparent in plane-polarized light. It predominantly fills intergranular spaces as irregular to spheroidal aggregates (Figure 4c and Figure 5i).

In the Shawan Sag glutenite reservoirs, irregular granular analcime coexists with heulandite cementing intergranular pores. Conversely, adjacent areas exhibit spheroidal analcime occurring on detrital grain surfaces under SEM, consistently associated with illite-smectite (I/S) mixed-layer clay minerals coating its periphery.

In the Shawan Sag, the coexistence of heulandite and analcime (Figure 4c) indicates zeolite formation during a stage of sustained supply of volcanic glass hydration products. Furthermore, the co-occurrence of analcime and heulandite within intergranular pores in the Shawan Sag (Figure 4c) records episodic fluctuations in the Si/Al ratio of diagenetic fluids, closely linked to elemental release during progressive volcanic glass hydration. In peripheral areas, laumontite shows replacements of plagioclase and coexists with calcite. The oriented replacement of laumontite along cleavage planes of andesitic plagioclase (Figure 5a–c,j) demonstrates its direct link with Ca²⁺ released during plagioclase albitization (Figure 5c). The assemblage of laumontite with calcite (Figure 5g,k,l) suggests the potential transformation of laumontite to calcite under increasing pCO₂ conditions.

5. Discussion

5.1. Contrast in Genesis of Zeolites Between the Shawan Sag and Adjacent Areas

The genesis of zeolites is complex, with systematic studies by domestic and international scholars generally attributing their formation to hydration alteration of volcanic glass in tuff [5,6,7,19,20,21,22,23] and albitization of plagioclase [8,22,23]. Owing to the distinct sediment provenance, the two regions exhibit substantial differences in source material composition. Based on comprehensive analysis of mineral characteristics, paragenetic relationships, associated mineral assemblages, and elemental distribution patterns of zeolite cements in the study area, it is concluded that zeolites in the Shawan Sag primarily formed through hydration of volcanic glass in tuff, whereas zeolites in the peripheral areas of the sag were mainly generated by albitization of plagioclase derived from andesite.

The Lower Permian reservoirs in the Shawan Sag contain abundant tuff fragments. Hydration of volcanic glass within these fragments, driven by changes in temperature, pressure, and fluid chemistry, releases substantial metal cations (K⁺, Na⁺, Ca²⁺, Mg²⁺) [5,6], creating an alkaline diagenetic environment that provides essential material foundations for zeolite formation. With increasing burial depth and temperature, clinoptilolite consumes significant K⁺ and Ca²⁺ to precipitate first [14]. However, deep burial in the Shawan Sag has transformed clinoptilolite into stable minerals, explaining its absence in our study. As an early-stage unstable mineral, clinoptilolite is replaced by analcime and albite [14]. In clinoptilolite, Na⁺ and Ca²⁺ are consumed by albite and analcime, whereas K⁺ is fixed in illite-smectite mixed-layer minerals and authigenic K-feldspar. Coexisting analcime and heulandite in the reservoirs (Figure 4c) indicate early zeolite precipitation lowered fluid pH, facilitating silica-rich heulandite formation (Figure 4f) [5,24,25]. Subsequent Ca²⁺ enrichment converts heulandite to laumontite [15,25,26], reducing Si/Al ratios (Figure 4i). Based on the analysis of mineral transformation relationships described above, the zeolite evolution pathway is determined as: Volcanic glass → Clinoptilolite → Analcime → Heulandite → Laumontite (Figure 6a).

In the Lower Permian reservoirs of adjacent areas to the Shawan Sag, andesite fragments dominate the source material. These fragments contain abundant plagioclase minerals, with weathering during transport preserving relatively stable plagioclase cores, resulting in high ca-rich plagioclase content in adjacent areas. Albitization of plagioclase is pervasive in adjacent areas, coexisting with laumontite (Figure 5a–c,j). Diagenetic fluids enriched in Na⁺ and SiO₂ facilitate albitization, which releases Ca²⁺ essential for laumontite precipitation (Figure 6b) [14,16,22,27,28,29,30,31,32].

5.2. Contrast in Pore Types Between the Shawan Sag and Adjacent Areas

This study reveals significant differences in pore types and developmental characteristics between the Shawan Sag and adjacent areas. In the Shawan Sag, grain-edge fractures—developing along laumontite-grain boundaries—form the predominant pore system (Figure 7). Under fluorescence microscopy, these fractures display reddish-brown fluorescence, indicating asphaltene-dominated bitumen components [28] (Figure 8a). The zeolite evolution pathway involves mineral density changes and crystalline water release, causing cement shrinkage and ultimately generating characteristic grain-edge fractures along laumontite-detrital grain contacts [15,16]. Intergranular dissolution pores mainly result from laumontite dissolution.

Adjacent areas feature intergranular dissolution pores as the dominant pore type. Thin-section and SEM observations show these pores formed by dissolution of laumontite and calcite (Figure 9), with some laumontite dissolution voids filled by bitumen (Figure 9c). Due to its crystalline structure, laumontite dissolution exhibits irregular serrated edges (Figure 5e,h,i).

5.3. Impact of Zeolites on Petrophysical Properties

To investigate the controlling effect of zeolite cementation on reservoir quality, this study integrates thin-section point-counting data with petrophysical measurements. The integrated data reveal that the Shawan Sag is characterized by the co-occurrence of heulandite and laumontite (with average contents of approximately 7.5% and 6.0%, respectively), whereas adjacent areas are generally devoid of heulandite but contain higher abundances of laumontite (averaging ~15.0%), accompanied by comparatively higher porosity. As illustrated in Figure 10, laumontite content in the Shawan Sag is lower than in adjacent areas, and porosity further decreases with increasing heulandite content. Based on the genetic analysis of zeolites and supporting experimental evidence, we propose that heulandite, with its high Si/Al ratio, exhibits strong dissolution resistance. In contrast, laumontite, characterized by a low Si/Al ratio, is prone to transformation into soluble calcite. Consequently, higher laumontite content is conducive to the development of porosity in the reservoir.

5.4. Controls of Zeolite Genesis on Pore Types in the Shawan Sag and Adjacent Areas

The genetic divergence of zeolites between the Shawan Sag and adjacent areas directly controls the development characteristics of pore types (Figure 11). In the Lower Permian reservoirs of the Shawan Sag, tuff fragments dominate the source material. Heulandite exhibits strong dissolution resistance due to its high Si content and large Si/Al ratio, hindering effective pore development and contributing minimally to porosity enhancement (Figure 4b). Laumontite evolution involves mineral density changes and crystalline water release, causing cement shrinkage and forming characteristic grain-edge fractures along laumontite-detrital grain boundaries, with fractures dominating the pore system.

Adjacent areas feature andesite fragments as the primary source material. Plagioclase albitization releases Ca²⁺ into pore fluids, providing the material basis for laumontite precipitation. Previous studies on Triassic Yanchang Formation sandstone reservoirs in the Ordos Basin suggested laumontite forms from calcite and kaolinite [10,29], but microscopic evidence shows calcite postdates laumontite formation (Figure 5k,l and Figure 9d). Meteoric leaching and organic decarboxylation in the Jiamuhe Formation elevate pCO₂, triggering laumontite dissolution. Released Ca²⁺ combines with CO₂ to form calcite [30,33] (Figure 9). Dissolution of laumontite and calcite develops pores dominated by dissolution voids.

This comparative study of sediment source, zeolite genesis, evolution, and pore types in glutenite reservoirs reveals that provenance differences control both zeolite pathways and pore architectures. In the Shawan Sag’s Lower Permian, volcanic glass hydration generates heulandite, whose dissolution resistance limits effective porosity development. Conversely, plagioclase albitization consumes SiO₂, inhibiting quartz cementation (Figure 6). Increasing pCO₂ converts laumontite to soluble calcite, enhancing dissolution porosity.

6. Conclusions

This study leads to the following conclusions:

• Significant differences exist in sediment source compositions between the Shawan Sag and adjacent areas (Chepaizi, Zhongguai). The Shawan Sag is dominated by tuff fragments with relatively high quartz content, whereas adjacent areas feature andesite fragments with substantially higher plagioclase content. Whole-rock XRD analyses further confirm quartz predominance in the Shawan Sag versus plagioclase dominance in adjacent areas. These provenance differences directly drive mineral enrichment contrasts, establishing the foundation for divergent zeolite genesis and pore systems.
• Zeolite types and origins in the study area are controlled by sediment source compositions. The Shawan Sag primarily develops laumontite, heulandite, and minor analcime, formed through hydration of volcanic glass in tuff: clinoptilolite → analcime → heulandite → laumontite. Adjacent areas exhibit zeolites generated by albitization of plagioclase in andesite fragments, with released Ca²⁺ providing the material basis for laumontite precipitation.
• Zeolite genetic differences between the Shawan Sag and adjacent areas shape pore system differentiation. In the Sag, zeolite evolution involves mineral density changes and crystalline water release, resulting in pore systems dominated by grain-edge fractures. In adjacent areas, the albitization of plagioclase and the transformation of laumontite to calcite provide the material basis for subsequent dissolution, resulting in a pore type dominated by intergranular dissolution pores. Provenance differences control both zeolite genesis mechanisms and pore type differentiation.
• The zeolite evolution pathway via volcanic glass hydration produces dissolution-resistant heulandite, constraining reservoir quality enhancement. Conversely, the albitization of Ca-rich plagioclase inhibits quartz precipitation by consuming SiO₂, and under elevated pCO₂ conditions, facilitates the transformation of laumontite to soluble calcite. This transformation enhances reservoir quality by generating easily dissolvable minerals.