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陆相湖盆的几何形态和充填样式主要受控于构造运动、湖平面升降和沉积物供给[1]。在稳定的坳陷背景下,沉积物供给和不同频次的气候变化共同控制着湖泊的演化[2]。与湖泊的主动扩张相对,湖泊的消亡(即湖平面下降)一般有两种形式,一种是气候不断干旱背景下湖域面积萎缩和湖平面的主动下降(即强制湖退),在我国中西部大多数现代湖泊较为常见(如岱海湖、鄂尔多斯盆地和准噶尔盆地)[3⁃7];另一种则是潮湿气候下沉积物快速充填湖泊导致陆地面积持续增大和基准面降低(即正常湖退),例如鄱阳湖和渤海湾盆地[3⁃4,8⁃9]。湖泊的萎缩和消亡一般是以上两种湖退方式的循环和多期叠加,但是不同期次主要以怎样的方式消亡未受到普遍重视。
国内外学者根据构造演化和基准面变化提出了陆相湖盆“坡折带控砂”和“湖岸线控砂”两种控砂机理,后者更适用于基准面高频变化的浅水坳陷湖盆砂体展布规律[10⁃12]。在不考虑风浪和湖流作用的前提下,湖平面在三角洲的下平原内波动,在最高和最低湖泛面之间形成多期岸线的水上分流河道砂体和河—坝复合砂体,前缘则形成河—坝复合砂体和河口坝砂体[13⁃14]。然而,国内外学者更重视高频基准面变化对陆相湖盆砂体类型的控制作用,常忽视沉积微相和复合砂体的时空分布对湖泊不同演化期次的低频响应。据此,以饶阳凹陷肃宁—大王庄构造带为例,利用岩心、测录井和三维地震等资料,综合岩石学和地震沉积学两种证据,分析和总结研究区古湖泊演变的过程和期次,建立稳定坳陷背景下湖泊多期次扩张—消亡低频演化模式,并分析该模式与沉积微相时空分布的关系。
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饶阳凹陷是渤海湾盆地西北部冀中坳陷的次一级负向半地堑式构造单元,是冀中坳陷中南部最大的富油凹陷,面积约6 300 km2。肃宁—大王庄地区整体为一东抬西倾的鼻状构造,面积约490 km2,东北为河间—窝北洼槽,西南为留西洼槽,探明地质储量约7×107 t。向河间洼槽方向发育弧状断裂带,洼槽中心断裂不发育[15]。下渐新世时期,肃宁—大王庄地区位于饶阳凹陷中央隆起带西北部缓坡带,东南邻两个沉积中心(现河间洼槽和留西洼槽所在位置),与东南部陡坡带相对(图1)[15⁃16]。
图 1 饶阳凹陷肃宁—大王庄地区地理位置和下渐新统顶部断裂分布
Figure 1. Location of fault systems at the top of the Lower Oligocene in the Suning⁃Dawangzhuang area of the Raoyang Sag
饶阳凹陷渐新世以来的构造演化可以划分为三个阶段:盆地抬升充填期I(Es2)、盆地扩张深陷期(
图 2 肃宁—大王庄地区古近系构造演化和地层特征
Figure 2. Tectonic evolution and stratigraphic features during the Paleogene in the Suning⁃Dawangzhuang area
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三角洲相可划分为三角洲平原亚相、三角洲前缘亚相和前三角洲亚相,在研究区
图 3 肃宁—大王庄地区下渐新统单井相划分
Figure 3. Sedimentary facies analyses in the Lower Oligocene, Suning⁃Dawangzhuang area
图 4 肃宁—大王庄地区下渐新统典型岩心照片
Figure 4. Photographs of typical cores from the Lower Oligocene, Suning⁃Dawangzhuang area
湖泊相在研究区
选取40余口探井,在岩心相分析的基础上利用GR测井曲线形态识别出11种沉积微相,重点统计5种偏砂相在不同沉积时期的出现频率(图5)。由于三角洲前缘分流河道总是侵蚀前期的河口坝,叠覆于河口坝之上形成“坝上河”,这种垂向叠置关系在一定程度上反映了高频基准面的变化,故在水下分流河道和河口坝的基础上增加一种砂体类型,称为河—坝复合体[22⁃27]。这也意味着统计中的“分流河道”是指三角洲平原水上分流河道,而“河口坝”则是指未被河道下切的完整河口坝(图5a)。总体上,分流河道的占比最高,河—坝复合体次之,其余沉积微相比例较小。自B时期至E时期,分流河道占比由30%增长至50%,河—坝复合体占比由20%增长至40%,而河口坝、席状砂和远砂坝的数量逐渐减少。另外,除了D沉积时期,B、C和E沉积时期偏砂相数量是增加的(图5b)。钻遇的分流河道和河—坝复合体指示着湖泊逐渐消亡的过程。
图 5
Figure 5. Types and distribution of sedimentary microfacies,
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沉积物粒度和颜色是判断沉积环境的重要指标。根据机械沉积分异原理,随着河流和湖泊水动力逐渐减弱,向湖方向沉积物粒径减小,即自湖泊边缘至湖中心呈现粗砂—细砂—粉砂—泥的平面展布规律。随着湖域萎缩和水深变浅,粗粒陆源碎屑向湖进积,自下而上“粒度由细变粗、泥岩颜色由暗及红”的演化序列[28]。
宁68井的岩心描述可以看出,Es1sIII油组发育一套暗色泥岩与薄层灰白色砂岩互层,指示长期的水下还原环境;而
图 6 宁68井岩心相分析
Figure 6. Well Ning 68 core analysis
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暗色泥岩一般形成于长期的水下低能环境,其厚度的变化趋势与古水深呈正相关,可以反映古水深的变化趋势[21]。通过统计研究区井点的暗色泥岩厚度并绘制等值线图,从而表征古水深的分布,0 m等值线可以定性的代表某一沉积时期长期稳定的湖岸线位置。结果表明,A~E沉积时期,暗色泥岩的分布范围逐渐减小,从早期的全区分布最终缩小到河间洼槽,指示古水深变浅、湖泊面积减小的趋势,残余湖泊的位置位于河间洼槽(图7)。
图 7 肃宁—大王庄地区下渐新统暗色泥岩厚度分布
Figure 7. Thickness maps of Lower Oligocene dark mudstone, Suning⁃Dawangzhuang area
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90°相位转换后的地震剖面的0 mm振幅对应岩性界面,地震反射同相轴则与地质体具有良好的对应关系(图2)。T3反射层顶拉平后,同相轴的产状可以反映三角洲的前积角,进而定性的反映水深。三角洲相总体上呈现断续中—弱振幅的偏砂相,顺物源方向自下而上显示叠瓦状前积和隐性(叠瓦状)前积,垂直物源方向则呈现透镜状。滨浅湖亚相和深湖—半深湖亚相分别呈现连续中—弱振幅的偏泥相和连续强振幅的偏泥相。垂向上,地震反射自下而上由连续强振幅偏泥相和叠瓦状前积的偏砂相向隐性前积转化,指示水深向上变浅的趋势(图8)。
图 8 肃宁—大王庄地区下渐新统地震反射特征(90°相位转换后,剖面位置见图1)
Figure 8. Seismic reflection features of the Lower Oligocene, Suning⁃Dawangzhuang area after 90° phasing (see location in Fig.1)
均方根振幅属性与砂岩厚度具有良好的相关性,可以反映三角洲等陆源粗碎屑体系的平面展布[29]。通过分析均方根振幅的数值正态分布,将地震属性切片归一化处理,归一化均方根振幅的中值可以近似作为陆地和湖泊的分界线。结果表明,A~E沉积时期,湖泊面积分别约占研究区的75%、70%、50%、30%和10%,A和B沉积时期湖域缩小速度较慢,C~E时期湖域快速萎缩,最终局限于河间洼槽(图9)。
图 9 肃宁—大王庄地区下渐新统归一化均方根振幅属性切片
Figure 9. Normalized RMS amplitude stratal slices of the Lower Oligocene, Suning⁃Dawangzhuang area
综上所述,饶阳凹陷肃宁—大王庄构造带下渐新统垂向上砂岩粒度由细变粗、泥岩颜色由暗变红、地震前积反射由叠瓦状向隐性转变、陆源粗碎屑沉积体系面积增大,这些趋势代表着湖域面积萎缩和水体深度变浅的过程,指示着湖盆稳定坳陷背景下,渐新世时期饶阳凹陷古湖泊经历了一次完整的扩张(A期)至消亡(B~E期)的低频演化过程。
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在沉积微相类型分析的基础上,利用归一化均方根振幅属性切片、自然伽马测井曲线形态和砂地比绘制了
图 10 肃宁—大王庄地区下渐新统砂地比分布
Figure 10. Sand⁃to⁃bed ratio contour maps in the Lower Oligocene, Suning⁃Dawangzhuang area
图 11 肃宁—大王庄地区下渐新统沉积微相演化
Figure 11. Sedimentary microfacies maps of the Lower Oligocene, Suning⁃Dawangzhuang area
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这一时期,缓坡带主要发育三角洲前缘—滨浅湖沉积体系,陡坡带局部发育近岸水下扇沉积体系。三角洲的延伸范围相对较小且以前缘为主,介于7~12 km。早期的分流河道和河口坝被改造为平行于岸线的椭圆状或长条状滩坝,单个滩坝面积约48 km2(图11a)。这说明研究区湖平面升高,水体迅速加深,形成了湖域面积较大的深水—半深水湖盆,河流的进积作用较弱,风浪和湖流作用较强。
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这一时期,缓坡带和陡坡带均发育三角洲前缘—滨浅湖沉积体系,在研究区中央呈汇聚趋势。缓坡带三角洲前缘的面积扩大明显,来自不同物源的沉积物不断充填湖盆,指状河—坝复合体延伸距离增大,以西南部三角洲最为明显且进积方向逐渐偏向河间洼槽(图11b)。这说明湖泊水体较上一时期略微变浅,沉积物保持较高的速率充填湖泊,湖泊以正常湖退为主,但是由于可容纳空间依然很大,湖泊面积整体上没有显著减小。
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这一时期,缓坡带和陡坡带均发育三角洲平原—三角洲前缘—滨浅湖沉积体系,两个方向的物源在研究区中央汇聚并向河间洼槽进积,三角洲平原的面积迅速扩大,面积约1 152 km2,三角洲前缘和湖泊局限于河间洼槽及周缘,仅是三角洲平原面积的三分之一。三角洲平原分流河道的分布很广,分支较多,形成密集河网,在末端形成大量指状河口坝(图11c)。这说明河流处于洪水期,具有较强的水动力和充足的物源供给。随着沉积物的持续供给,湖泊被大面积充填,水体变浅且地形坡度逐渐平缓,湖泊以正常湖退为主。
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这一时期,缓坡带和陡坡带均发育三角洲平原—三角洲前缘—滨浅湖沉积体系,两个方向的物源向河间洼槽进一步汇聚,三角洲平原的面积较上一期没有明显增加,三角洲前缘和湖泊的面积略有减小,河口坝分布于分流河道的末端,河流支流较上一期明显减少且呈树枝状分布(图10d)。这说明河流能量减弱并进入枯水期,水动力条件减弱导致沉积物的搬运能力下降,湖泊仅小幅度的收缩,湖泊以强制湖退为主。
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这一时期,缓坡带和陡坡带均发育三角洲平原—三角洲前缘—滨浅湖沉积体系,三角洲平原的面积较上一期有所增加,湖泊面积进一步大幅度缩小,分流河流逐渐将湖泊封闭。三角洲平原分流河道继续决口分叉,并在向源方向形成零星的河漫湖泊,在末端形成大量指状河口坝,部分分流河道逐渐向现今的沉积中心白洋淀汇聚(图10e)。河流的支流数量有所增加指示河流水动力和沉积物供给也相应增强,湖泊以正常湖退为主。
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早渐新世时期饶阳凹陷古湖泊演化可以概括为一次完整的扩张—消亡过程,不同的湖泊演化时期造就了不同微相砂体的平面展布(图11,12)。湖泊快速扩张时期,湖平面上涨导致早期形成的三角洲前缘分流河道和河口坝被湖浪和风暴改造为滩坝(图11a);湖泊的被动收缩(即正常湖退)造就早期广阔的三角洲前缘指状河—坝复合砂体和后期大规模三角洲平原网状分流河道体系(图11b,c,e);湖泊的主动收缩(即强制湖退)则与树枝状分流河道体系相对应(图11d)。
图 12 古湖泊多期次扩张—消亡演化模式
Figure 12. Multi⁃stage expansion⁃to⁃regression model of paleo⁃lakes
低频的湖泊演化对不同类型复合砂体的垂向分布也具有很大影响。首先,高频湖平面的波动范围有限,湖泊的低频的消亡过程可造成相同类型的复合砂体较上一期向湖迁移,垂向上形成不同类型复合砂体的叠置,分流河道和河—坝复合体数量向上增加,河口坝数量向上减少(图5b、图12)。再者,随着三角洲面积的扩大,以分流河道为主的偏砂相数量较多,正常湖退起主导作用使河—坝复合体的数量也有所增多。相反,干旱气候背景下湖泊消亡以强制湖退为主,虽然三角洲面积扩大,但是大部分分流河道进入枯水期或被废弃,导致河道类型以水上分流河道为主且数量较少(图11b、图12)。
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(1) 饶阳凹陷肃宁—大王庄构造带下渐新统自下而上三角洲平原分流河道增加、砂岩粒度由细变粗、泥岩颜色由暗变红、暗色泥岩分布范围减小、地震前积反射由叠瓦状向隐性转变、陆源粗碎屑沉积体系面积增大,这些证据均证明了湖域面积的萎缩和水体深度的变浅,指示古湖泊一次完整的扩张—消亡低频演化过程。
(2) 饶阳凹陷肃宁—大王庄构造带早渐新世古湖泊演化可以划分为5个期次,分别为快速主动扩张期、缓慢被动收缩期、快速被动收缩期、缓慢主动收缩期和缓慢被动消亡期。
(3) 古湖泊的扩张—消亡低频演化过程影响着不同类型复合砂体的垂向分布。湖泊主动扩张将早期形成的分流河道和河口坝改造为滩坝,正常湖退背景下湖泊的充填造就广阔的三角洲前缘河—坝复合砂体和三角洲平原网状分流河道体系,而强制湖退背景下湖泊的收缩则形成树枝状分流河道体系。湖泊的消亡使相同类型的复合砂体较上一期向湖迁移,垂向上形成不同类型复合砂体的叠置。
A Multi-stage Expansion-to-regression Model of Paleo-lakes in Down-warp Lacustrine Basins
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摘要: 陆相湖盆沉积微相研究主要着眼于复合砂体的平面展布规律和垂向叠置关系,很少与多期次、多种湖退机制的低频湖泊演化模式建立联系。以饶阳凹陷肃宁—大王庄地区下渐新统为例,在岩心观察的基础上,结合测录井和三维地震资料,利用岩石学和地震沉积学两种证据分析古湖泊的演化过程和期次,建立多期次古湖泊扩张—消亡演化模式。研究表明:湖盆稳定坳陷背景下,早渐新世时期饶阳凹陷古湖泊经历了一次完整的扩张至消亡的低频演化过程,可以划分为快速主动扩张期、缓慢被动收缩期、快速被动收缩期、缓慢主动收缩期和缓慢被动消亡期。湖泊的主动扩张将早期形成的分流河道和河口坝改造为滩坝,正常湖退背景下湖泊的充填造就广阔的三角洲前缘河—坝复合砂体和三角洲平原网状分流河道体系,而强制湖退背景下湖泊的收缩则形成树枝状分流河道体系。湖泊的持续消亡可造成相同类型的复合砂体较上一期向湖迁移,垂向上则形成不同类型复合砂体的叠置。Abstract: Studies of the spatial distribution of sedimentary microfacies in continental lacustrine basins have mainly concentrated on high-frequency lake level changes. However, this is unrelated to low-frequency lacustrine evolutional stages and lake regression processes. This study was based on core observation, combining well logs and 3D seismic volumes to restore the types of sedimentary microfacies in the Oligocene interval of rocks in the Suning-Dawangzhuang area. The stages and features of lacustrine evolution were investigated by integrating lithological and seismic sedimentological evidence. The spatial distribution at different stages of lacustrine evolution is also discussed. It was found that, against the background of stable down-warp lake basins, the ancient lake in the Raoyang Sag underwent a complete low-frequency evolutional expansion⁃extinction cycle in the Early Oligocene. This occurred in stages: rapid active expansion followed by slow passive contraction, rapid passive contraction, slow active contraction and slow passive extinction. During active expansion, the early distributary channels and mouth bars were reworked into beach bars. The passive contraction of the lake during normal lake regression created broad delta-front channel-mouth bar composite sand bodies and delta-plain distributary channel networks. The active contraction of the lake resulting from forced lake regression formed a dendritic distributary channel system. The continuous extinction process of the lake caused these various types of composite sand body to migrate towards the lake, unlike in the previous stage, thus vertically superposing the different types of composite sand body.
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图 1 饶阳凹陷肃宁—大王庄地区地理位置和下渐新统顶部断裂分布
Figure 1. Location of fault systems at the top of the Lower Oligocene in the Suning⁃Dawangzhuang area of the Raoyang Sag
Fig.1
图 2 肃宁—大王庄地区古近系构造演化和地层特征
Figure 2. Tectonic evolution and stratigraphic features during the Paleogene in the Suning⁃Dawangzhuang area
Fig.2
图 3 肃宁—大王庄地区下渐新统单井相划分
(a)宁68井Ed3IV油组单井相分析;(b)宁68井
Figure 3. Sedimentary facies analyses in the Lower Oligocene, Suning⁃Dawangzhuang area
(a) Ed3IV oil group, well Ning 68; (b)
图 4 肃宁—大王庄地区下渐新统典型岩心照片
(a)杂色细砂岩,平行层理和斜层理,底部冲刷面,含泥砾,Ed3IV油组,宁68井,2 968.8 m;(b)杂色泥质粉砂岩,上攀交错层理,Ed3V油组,宁68井,2 969.2 m;(c)红棕色泥岩,Ed3IV油组,宁68井,2 913.0 m;(d)灰白色细砂岩,平行层理,中部冲刷面,含泥砾,
Figure 4. Photographs of typical cores from the Lower Oligocene, Suning⁃Dawangzhuang area
(a) variegated fine sandstone, parallel bedding and oblique bedding, bottom scouring surface, containing mud and gravel, Ed3IV oil group, well Ning 68, 2 968.8 m; (b) variegated argillaceous siltstone, ascending cross⁃bedding, Ed3V oil group, well Ning 68, 2 969.2 m; (c) reddish⁃brown mudstone, Ed3IV oil group, well Ning 68, 2 913.0 m; (d) grayish⁃white fine sandstone, parallel bedding, middle scouring surface, containing mud and gravel,
图 5
(a)沉积微相类型和自然伽马曲线形态;(b)沉积微相频率统计
Figure 5. Types and distribution of sedimentary microfacies,
(a) gamma⁃ray log patterns; (b) frequency of occurrence
图 7 肃宁—大王庄地区下渐新统暗色泥岩厚度分布
(a)A期暗色泥岩厚度等值线图;(b)B期暗色泥岩厚度等值线图;(c)C期暗色泥岩厚度等值线图;(d)D~E期暗色泥岩厚度等值线图
Figure 7. Thickness maps of Lower Oligocene dark mudstone, Suning⁃Dawangzhuang area
(a) stage A; (b) stage B; (c) stage C; (d) stages D and E
图 8 肃宁—大王庄地区下渐新统地震反射特征(90°相位转换后,剖面位置见图1)
Figure 8. Seismic reflection features of the Lower Oligocene, Suning⁃Dawangzhuang area after 90° phasing (see location in Fig.1)
Fig.8
图 9 肃宁—大王庄地区下渐新统归一化均方根振幅属性切片
(a)A期;(b)B期;(c)C期;(d)D期;(e)E期
Figure 9. Normalized RMS amplitude stratal slices of the Lower Oligocene, Suning⁃Dawangzhuang area
(a) stage A; (b) stage B; (c) stage C; (d) stage D; (e) stage E
图 10 肃宁—大王庄地区下渐新统砂地比分布
(a)A期;(b)B期;(c)C期;(d)D期;(e)E期
Figure 10. Sand⁃to⁃bed ratio contour maps in the Lower Oligocene, Suning⁃Dawangzhuang area
(a) stage A; (b) stage B; (c) stage C; (d) stage D; (e) stage E
图 11 肃宁—大王庄地区下渐新统沉积微相演化
(a)A期沉积微相分布图;(b)B期沉积微相分布图;(c)C期沉积微相分布图;(d)D期沉积微相分布图;(e)E期沉积微相分布图
Figure 11. Sedimentary microfacies maps of the Lower Oligocene, Suning⁃Dawangzhuang area
(a) stage A; (b) stage B; (c) stage C; (d) stage D; (e) stage E
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[1] 纪友亮,杜金虎,赵贤正,等. 冀中坳陷饶阳凹陷古近系层序地层学及演化模式[J]. 古地理学报,2006,8(3):397-406. Ji Youliang, Du Jinhu, Zhao Xianzheng, et al. Sequence stratigraphy and evolution models of the Paleogene in Raoyang Sag, Jizhong Depression[J]. Journal of Palaeogeography, 2006, 8(3): 397-406. [2] 杜威,纪友亮,李其海,等. 不同沉积过程尺度下正演数值模拟研究进展及油气地质意义[J]. 油气地质与采收率,2020,27(2):62-71. Du Wei, Ji Youliang, Li Qihai, et al. Sedimentary forward numerical modeling at different sedimentary scales: Progress and hydrocarbon significance[J]. Petroleum Geology and Recovery Efficiency, 2020, 27(2): 62-71. [3] 操应长. 断陷湖盆中强制湖退沉积作用及其成因机制[J]. 沉积学报,2005,23(1):84-90. Cao Yingchang. Sedimentation and its forming mechanism of the forced lacustrine regression in the rift lacustrine basin[J]. Acta Sedimentologica Sinica, 2005, 23(1): 84-90. [4] 杜威,纪友亮,张艺楼,等. 湖泊缓坡带细粒河控三角洲沉积演化和形态特征:沉积正演数值模拟和现代沉积实例的启示[J]. 石油学报,2021,42(1):33-44. Du Wei, Ji Youliang, Zhang Yilou, et al. Depositional evolution and geometrical features of lacustrine fine-grained river-dominated deltas at the gentle slope zone: Insights from sedimentary forward numerical modeling and modern case analyses[J]. Acta Petrolei Sinica, 2021, 42(1):33-44. [5] 陈彬滔,于兴河,王天奇,等. 岱海湖盆沿坡流与顺坡流相互作用的沉积响应[J]. 地球科学:中国地质大学学报,2014,39(4):399-410. Chen Bintao, Yu Xinghe, Wang Tianqi, et al. Sedimentary response to interaction between alongslope and downslope currents in Daihai Lake, North China[J]. Earth Science: Journal of China University of Geosciences, 2014, 39(4): 399-410. [6] 李元昊,刘池洋,独育国,等. 鄂尔多斯盆地西北部上三叠统延长组长8油层组浅水三角洲沉积特征及湖岸线控砂[J]. 古地理学报,2009,11(3):265-274. Li Yuanhao, Liu Chiyang, Du Yuguo, et al. Sedimentary characteristics of shallow water delta and lake shoreline control on sandbodies of Chang 8 oil-bearing interval of the Upper Triassic Yanchang Formation in northwestern Ordos Basin[J]. Journal of Palaeogeography, 2009, 11(3): 265-274. [7] 房亚男,吴朝东,王熠哲,等. 准噶尔盆地南缘中—下侏罗统浅水三角洲类型及其构造和气候指示意义[J]. 中国科学:技术科学,2016,46(7):737-756. Fang Yanan, Wu Chaodong, Wang Yizhe, et al. Lower to Middle Jurassic shallow-water delta types in the southern Junggar Basin and implications for the tectonic and climate[J]. Scientia Sinica Technologica, 2016, 46(7): 737-756. [8] 金振奎,李燕,高白水,等. 现代缓坡三角洲沉积模式:以鄱阳湖赣江三角洲为例[J]. 沉积学报,2014,32(4):710-723. Jin Zhenkui, Li Yan, Gao Baishui, et al. Depositional model of modern gentle-slope delta: A case study from Ganjiang delta in Poyang Lake[J]. Acta Sedimentologica Sinica, 2014, 32(4): 710-723. [9] 吕传炳,程同冉,张峰,等. 浅水三角洲沉积特征及其油气勘探意义:以渤海湾盆地霸县凹陷岔河集构造带沙一上亚段为例[J]. 新疆石油地质,2016,37(6):625-630. Chuanbing Lü, Cheng Tongran, Zhang Feng, et al. Depositional characteristics and hydrocarbon exploration significance of shallow-water deltas: A case study of upper Sha-1 member in Chaheji structural belt of Baxian Sag, Bohai Bay Basin[J]. Xinjiang Petroleum Geology, 2016, 37(6): 625-630. [10] 张莉,鲍志东,林艳波,等. 浅水三角洲砂体类型及沉积模式:以松辽盆地南部乾安地区白垩系姚家组一段为例[J]. 石油勘探与开发,2017,44(5):727-736. Zhang Li, Bao Zhidong, Lin Yanbo, et al. Genetic types and sedimentary model of sandbodies in a shallow-water delta: A case study of the First member of Cretaceous Yaojia Formation in Qian’an area, south of Songliao Basin, NE China[J]. Petroleum Exploration and Development, 2017, 44(5): 727-736. [11] 刘君龙,纪友亮,杨克明,等. 浅水湖盆三角洲岸线控砂机理与油气勘探意义:以川西坳陷中段蓬莱镇组为例[J]. 石油学报,2015,36(9):1160-1073,1155. Liu Junlong, Ji Youliang, Yang Keming, et al. Mechanism of lake shoreline control on shoal water deltaic sandbodies and its significance for petroleum exploration: A case study of Penglaizhen Formation in the middle part of western Sichuan Depression[J]. Acta Petrolei Sinica, 2015, 36(9): 1160-1073, 1155. [12] 赖洪飞,秦智,王洪君,等. 高频基准面旋回控制下浅水三角洲及其砂体发育模式:以松辽盆地扶余油田白垩系泉头组为例[J]. 古地理学报,2017,19(4):609-622. Lai Hongfei, Qin Zhi, Wang Hongjun, et al. Development pattern of shallow-water delta and sandbodies under control of high-frequency base-level cycles: A case study of the Cretaceous Quantou Formation in Fuyu oilfield, Songliao Basin[J]. Journal of Palaeogeography, 2017, 19(4): 609-622. [13] 吴胜和,徐振华,刘钊. 河控浅水三角洲沉积构型[J]. 古地理学报,2019,21(2):202-215. Wu Shenghe, Xu Zhenhua, Liu Zhao. Depositional architecture of fluvial-dominated shoal water delta[J]. Journal of Palaeogeography, 2019, 21(2): 202-215. [14] 吕文睿,张峰,纪友亮,等. 饶阳凹陷大王庄地区沙一上亚段河口坝结构对油藏开发的影响[J]. 岩性油气藏,2020,32(4):143-154. Wenrui Lü, Zhang Feng, Ji Youliang, et al. Influence of estuary bar structure on reservoir exploitation of upper Sha-1 submember in Dawangzhuang area, Raoyang Sag[J]. Lithologic Reservoirs, 2020, 32(4): 143-154. [15] 邹娟,戴俊生,张丹丹,等. 构造活动强度划分断陷盆地构造区划:以饶阳凹陷为例[J]. 石油学报,2014,35(2):294-302,384. Zou Juan, Dai Junsheng, Zhang Dandan, et al. Structural divisions of rift basin based on the intensity of tectonic activity: A case study from the Raoyang Sag[J]. Acta Petrolei Sinica, 2014, 35(2): 294-302, 384. [16] 董大伟,李理,刘建,等. 冀中坳陷中北部新生代构造演化特征[J]. 石油与天然气地质,2013,34(6):771-780. Dong Dawei, Li Li, Liu Jian, et al. Cenozoic tectonic evolution in the north-central Jizhong Depression[J]. Oil & Gas Geology, 2013, 34(6): 771-780. [17] 邓爱居,张少华,李凤群,等. 饶阳凹陷肃宁地区新生代断裂活动及其对油气成藏的控制作用[J]. 油气地质与采收率,2017,24(3):18-24. Deng Aiju, Zhang Shaohua, Li Fengqun, et al. Cenozoic fault activity and its control on hydrocarbon accumulation in Suning area of Raoyang Sag, Bohai Bay Basin[J]. Petroleum Geology and Recovery Efficiency, 2017, 24(3): 18-24. [18] 张大智,纪友亮,张瑞峰,等. 饶阳凹陷古近系层序地层研究[J]. 地质调查与研究,2008,31(1):33-42. Zhang Dazhi, Ji Youliang, Zhang Ruifeng, et al. Research on the sequence stratigraphy of Eogene in Raoyang Depression[J]. Geological Survey and Research, 2008, 31(1): 33-42. [19] 曾洪流,赵贤正,朱筱敏,等. 隐性前积浅水曲流河三角洲地震沉积学特征:以渤海湾盆地冀中坳陷饶阳凹陷肃宁地区为例[J]. 石油勘探与开发,2015,42(5):566-576. Zeng Hongliu, Zhao Xianzheng, Zhu Xiaomin, et al. Seismic sedimentology characteristics of sub-clinoformal shallow-water meandering river delta: A case from the Suning area of Raoyang Sag in Jizhong Depression, Bohai Bay Basin, NE China[J]. Petroleum Exploration and Development, 2015, 42(5): 566-576. [20] 赵贤正,蒋有录,金凤鸣,等. 富油凹陷洼槽区油气成藏机理与成藏模式:以冀中坳陷饶阳凹陷为例[J]. 石油学报,2017,38(1):67-76. Zhao Xianzheng, Jiang Youlu, Jin Fengming, et al. Hydrocarbon accumulation mechanism and model of sub-sags in hydrocarbon-rich sag: A case study of Raoyang Sag in Jizhong Depression[J]. Acta Petrolei Sinica, 2017, 38(1): 67-76. [21] 殷杰,王权,郝芳,等. 渤海湾盆地饶阳凹陷沙一下亚段古湖泊环境与烃源岩发育模式[J]. 地球科学,2017,42(7):1209-1222. Yin Jie, Wang Quan, Hao Fang, et al. Palaeolake environment and depositional model of source rocks of the lower submember of sha1 in Raoyang Sag, Bohai Bay Basin[J]. Earth Science, 2017, 42(7): 1209-1222. [22] Du W, Ji Y, Chen G, et al. Cyclostratigraphy and astronomical tuning during the Oligocene in the Jizhong Depression, Bohai Bay Basin, northeastern China[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2020, 554: 109803. [23] 强小科,安芷生,宋友桂,等. 晚渐新世以来中国黄土高原风成红粘土序列的发现:亚洲内陆干旱化起源的新记录[J]. 中国科学:地球科学,2010,40(11):1479-1488. Qiang Xiaoke, An Zhisheng, Song Yougui, et al. New eolian red clay sequence on the western Chinese Loess Plateau linked to onset of Asian desertification about 25 Ma ago[J]. Science China Earth Sciences, 2010, 40(11): 1479-1488. [24] 董欣欣,丁仲礼,杨石岭,等. 晚渐新世中亚降温与干旱化[J]. 科学通报,2013,58(17):1680. Dong Xinxin, Ding Zhongli, Yang Shiling, et al. Synchronous drying and cooling in central Asia during Late Oligocene[J]. Chinese Science Bulletin, 2013, 58(17): 1680. [25] Liu Z H, Huang C J, Algeo T J, et al. High-resolution astrochronological record for the Paleocene-Oligocene (66-23 Ma) from the rapidly subsiding Bohai Bay Basin, northeastern China[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2018, 510: 78-92. [26] 袭著纲,国景星,赵晓颖. 冀中坳陷饶阳凹陷中北部古近纪沙河街组古生态分析[J]. 地球科学与环境学报,2011,33(4):358-363. Xi Zhugang, Guo Jingxing, Zhao Xiaoying. Palaeoecological analysis of Paleogene Shahejie Formation in north central Raoyang Sag of central Hebei Depression[J]. Journal of Earth Sciences and Environment, 2011, 33(4): 358-363. [27] 杜威,纪友亮,季梦瑶,等. 渤海湾盆地饶阳凹陷早渐新世高精度年代地层格架建立及意义[J]. 中国石油大学学报(自然科学版),2020,44(4):142-151. Du Wei, Ji Youliang, Ji Mengyao, et al. Establishment and significance of high-resolution Early Oligocene chronostratigraphic framework in Raoyang Sag, Bohai Bay Basin[J]. Journal of China University of Petroleum, 2020, 44(4): 142-151. [28] 邹才能,赵文智,张兴阳,等. 大型敞流坳陷湖盆浅水三角洲与湖盆中心砂体的形成与分布[J]. 地质学报,2008,82(6):813-825. Zou Caineng, Zhao Wenzhi, Zhang Xingyang, et al. Formation and distribution of shallow-water deltas and central-basin sandbodies in large open depression lake basins[J]. Acta Geologica Sinica, 2008, 82(6): 813-825. [29] Li W, Yue D L, Wu S H, et al. Characterizing meander belts and point bars in fluvial reservoirs by combining spectral decomposition and genetic inversion[J]. Marine and Petroleum Geology, 2019, 105: 168-184. [30] 刘君龙,孙冬胜,纪友亮,等. 川西晚侏罗世前陆盆地浅水三角洲砂体分布特征与叠置模式[J]. 石油与天然气地质,2018,39(6):1164-1178. Liu Junlong, Sun Dongsheng, Ji Youliang, et al. Distribution characteristics and superimposition pattern of the Late Jurassic shallow water deltic sand body in the foreland basin of western Sichuan Depression[J]. Oil & Gas Geology, 2018, 39(6): 1164-1178. -
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