Zircon U-Pb ages, Hf isotope and extensional tectonics of monzogranite in the Hansumu area of southern Great Khingan
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摘要:
大兴安岭南段罕苏木地区出露大面积的二长花岗岩,为了正确认识该岩体的形成时代及其伸展构造作用,本文采集相关样品,对罕苏木地区出露的二长花岗岩体开展了岩相学、LA-MC-ICP-MS锆石年代学和Hf同位素分析研究。研究结果表明:罕苏木地区二长花岗岩岩性为微细粒斑状含角闪黑云二长花岗岩和细粒斑状含黑云二长花岗岩,具有斑状和似斑状结构,块状构造。二长花岗岩中的锆石为岩浆成因,测得206Pb/238U年龄的加权平均值为(136±1)Ma(MSWD=1.4),属于早白垩世晚期岩浆活动的产物。这一结果与研究区及周边,甚至是与区域上中国东北地区114~145 Ma岩浆活动相吻合,都属于同一岩浆活动阶段的产物。罕苏木地区二长花岗岩锆石的εHf(t)值均为正值,变化范围为7.1~14.4,并且具有较年轻的二阶段模式年龄,TDM2为324~959 Ma。年轻的Hf同位素模式年龄,暗示在新元古代-晚古生代曾发生一次重要的地壳增生事件。结合区域地质,表明研究区二长花岗岩的岩浆可能是来源于从亏损地幔中新增生的年轻地壳发生部分熔融的产物,在侵位过程中受到了地壳或岩石圈地幔的混染,可能形成在造山后岩石圈伸展环境下,与古太平洋板块向欧亚大陆俯冲有关。
Abstract:Large area of monzogranite is outcropped in the Hansumu area of southern Great Khingan. In order to recognize the formation age of the rock and its tectonic significance, samples were collected from the monzogranite pluton to study its petrography, zircon LA-MC-ICP-MS age and Hf isotope. The results show that the pluton is composed of fine-grained porphyritic amphibolit-biotite monzogranite and fine-grained porphyritic biotite monzogranite with porphyritic and porphyritic structures and massive structures. The zircons from the monzogranite is of magmatic origin, and yields 206Pb/238U age of 136±1 Ma (MSWD=1.4), which suggests that the pluton was formed in the late Early Cretaceous. This result is strongly consistent with the study area and its surrounding areas, and even with the 114-145 Ma magmatic activities in the northeastern of China, indicating the products of the same magmatic activity stage. The monzogranite in the Hansumu area has positive εHf (t) values of 7.1 to 14.4 and young Hf two-stage model ages, and TDM2 is 324 to 959 Ma. Young Hf isotope model ages imply that this area could have experienced an important crustal accretion event during the Neoproterozoic-Late Proterozoic. Combined with regional geology, it is suggested that the monzogranite was likely derived from the partial melting of young mantle, and possibly was formed in a lithosphere extensional tectonics environment related to the subduction of the Paleo-Asian plate to Eurasia Plate.
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走滑断裂是沉积盆地中特殊而且力学机制复杂的断裂系统,走滑断裂及其破碎带本身是重要的储油气空间,同时,高角度的走滑断裂常常沟通地层深部流体,是油气运聚的输导体系,对储层的形成与油气的分布具有重要的控制作用。近期针对大型走滑断裂及其破碎带的直接钻探在塔里木盆地奥陶系层间岩溶区的塔中I号气田、哈拉哈塘油田和轮古东气田均取得了预期效果[1-4],极大地拓展了油气勘探开发领域,也使得对塔里木盆地走滑断裂的研究与认识更进一步深化。一方面加强走滑断裂的识别、构造样式的刻画及力学机制的研究[1-7];另一方面对走滑断裂破碎带结构的研究引起关注,张庆莲等[8],潘文庆等[9]对塔里木盆地西北缘的柯坪—巴楚露头区野外裂缝地质建模明确走滑断裂控制的裂缝发育带具有明显的分带性,距断层由近及远可细分为“破碎带、劈理带、菱形裂缝带、稀疏裂缝带”;邬光辉等[10]通过野外与井下地质建模,指出塔里木盆地奥陶系沿走滑断裂带走向上断裂相具有分段性和差异性,可定性分为高渗透相和致密相区;孙东等[11]通过地震储层正演明确断层面及断裂破碎带能产生串珠状反射。这些研究成果对认识走滑断裂破碎带在三维空间复杂结构及解译其与油气富集规律提供了新的思路和方法。
前期针对轮古东气田断裂系统的研究,由于受地震资料品质和勘探开发程度的限制,对走滑断裂的解释有待深入,对断裂破碎带及伴生裂缝发育特征研究较少[4],本文以最新处理完成的轮古东300 km2叠前深度偏移地震资料为基础,结合区域已有钻井资料综合分析轮古东气田走滑断裂的识别、发育特征、断裂破碎带的组合方式以及控储控藏特征,以期为该区进一步勘探开发提供指导。
1. 地质背景
轮古东气田地处新疆轮台县境内,构造上隶属于塔里木盆地塔北隆起轮南低凸起中部。奥陶纪地层发育齐全,可细分为上奥陶统桑塔木组、良里塔格组和吐木休克组(又称恰尔巴克组)、中奥陶统一间房组及中下奥陶统鹰山组和蓬莱坝组。
主要勘探目的层为一间房组和鹰山组,其次为良里塔格组,一间房组埋藏深度5050~6700 m,厚度10.5~42 m,发育台缘和台内丘滩复合体沉积,岩性以浅褐灰-灰褐色亮晶砂屑灰岩、亮晶鲕粒灰岩和亮晶藻屑砂屑灰岩为主,在AG35、AG621等井都发现托盘类生物礁。鹰山组自上而下可细分为4段:鹰一段(O1-2y1)、鹰二段(O1-2y2)、鹰三段(O1-2y3)和鹰四段(O1-2y4),本区绝大多数钻井仅钻揭鹰一段,主要发育亮晶砂屑灰岩、泥晶灰岩,为开阔台地相的台内滩和滩间海沉积。
研究区东邻草湖生油凹陷,南接满加尔生油坳陷,位于油气运移主要方向的前沿部位,构造位置十分有利。以近南北向轮东I号走滑断裂带为界,构造西缓东陡,总体为一东南倾大型斜坡(图 1),一间房组顶面构造高差1650 m,奥陶系油气主力产层一间房组在西北部受剥蚀而尖灭。储层以裂缝孔洞型储层为主,发育少量洞穴型储层,整体表现为受断裂和沉积相带分割,局部断块含少量边、底水的大型准层状凝析气藏[12-13]。
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图 1 轮古东气田构造断裂与储层预测叠合图Figure 1. Overlapping figure of structural fault and reservoir forecasting in Lungudong gas field2. 断裂与裂缝特征
2.1 地震资料断裂识别
平剖结合,多方法开展工区断裂解释,小断层产状较陡,主要根据上下地层即寒武系和良里塔格顶面存在断距和挠曲,以及地震同相轴存在变化进行识别[3]。在此基础上,通过沿层切片、相干属性等技术实现断裂与裂缝的平面识别,以垂直剖面为主精细解释断层。
2.1.1 断裂平面识别
相干体技术是一种不连续的检测手段,当地下有断层、裂缝或地质异常体(如洞穴、河道、串珠等)时,地层产生横向不均匀现象,相邻地震道之间的反射波在振幅、频率及相位等方面都将发生不同程度的变化,进而达到检测断层、反映岩性异常体的目的,相干体切片比常规切片能更好地表现断层和沉积特征。从沿层相干切片结果分析,中深层断裂平面上主要分4组:走滑断层主要呈近南北、北东和北西向3组断裂,且北东向断层错断北西向断层;逆冲断裂为近东西走向,主要位于工区西部(图 2~图 3)。石炭系以上以雁列式走滑断层和逆冲断裂为主,走滑断层主要发育近南北向以及两条近北东向断裂(图 4)。
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图 2 轮古东气田下寒武统底面up-down 20 ms相干属性图Figure 2. Up-down 20 ms coherent property of Lower Cambrian basal surface in Lungudong gas field![]()
图 3 轮古东气田一间房顶面up-down 20 ms相干属性图Figure 3. Up-down 20 ms coherent property of the top surface of Yijianfang Formation in Lungudong gas field![]()
图 4 轮古东气田石炭系双峰灰岩顶up-down 20 ms相干属性图Figure 4. Up-down 20 ms coherent property of Carboniferous double peak limestone top surface in Lungudong gas field2.1.2 断裂剖面识别
根据区域构造运动背景以及断层平剖面特征,研究区断裂可划分为3期4组。中晚加里东期走滑断裂、晚海西期逆冲断裂以及喜山期走滑断裂(图 1、图 5)。
早加里东期寒武系—中下奥陶统,塔北隆起稳定沉积,无大的构造活动,断裂不发育,沉积大套灰岩地层。中晚加里东期断裂开始活动,沉积地层由碳酸盐岩向碎屑岩过渡,发育近北西和北东向走滑断层,延伸距离约10~25 km,剖面上,断裂近乎陡直,向下断入震旦系,向上消失于奥陶系桑塔木组,断距一般小于100 m(图 5-c)。该期断层是晚加里东期寒武系—下奥陶统烃源岩的原油充注的主要通道,沿断层分布形成古油藏。
晚海西期受区域性南北向挤压应力作用,工区西部发育两条近东西走向的逆冲断裂(桑塔木南断裂和桑塔木北断裂),剖面上呈“y”字形特征,其中桑塔木北断裂是一条主断裂,东西延伸约18 km,断距大,垂向断距最大达200 m,断开层位多,上至三叠系底,下至寒武系、震旦系;桑塔木南断裂是桑塔木北断裂的一条大的伴生断裂,断开层位少,上部仅断开石炭系,下部消失在奥陶纪地层中,垂向断距最大达150 m(图 5-a)。桑塔木断裂控制了局部构造形态,构造脊部裂缝发育,井间连通性好。根据挤压应力的剪切分量分析,推测该时期南北向轮东1号走滑断裂已开始发育,整体表现为压扭性特征。
喜山期受张剪应力作用,贯穿工区的南北向轮东1号走滑断裂进一步活动,表现为右旋走滑特征,并伴生一些列北东-南西向次级走滑断裂,控制工区构造格局,轮东1号断裂区内延伸21.8 km,断开层位从基底至侏罗系,断距20~100 m。石炭系以下表现为压扭性质,在工区AG35和AG35-1井附近表现最为明显,奥陶系断面倾向多变,工区南部东倾,中部西倾,北部东倾,具有典型丝带状效应;同时平面上断层两盘高低关系一直在变化,具有明显海豚效应(图 5-b)。石炭系及以上地层剖面上表现为负花状构造,断层性质由压扭转化为张扭性质,呈明显负反转构造,平面上表现为雁列式右旋走滑特征。轮东I号断裂是喜山期寒武系原油裂解气的主要充注通道,沿断裂走向裂缝发育,天然气富集。
2.2 岩心薄片裂缝特征
由于碳酸盐岩储层强非均质性,储层发育井段往往发生漏失,取心困难,岩心分析仅代表基质物性[1]。研究区岩心常规物性分析孔隙度样品1259块,渗透率样品963块,平均孔隙度1.615%,平均渗透率2.82×10-3μm2。基质孔隙度差,次生的溶蚀孔、洞和裂缝是主要的储集空间,裂缝既是储集空间,又是渗滤通道。研究区9口井428.89 m岩心统计,共发育裂缝965条,其中未充填和半充填缝649条,占裂缝总数的67.3%,以倾角 > 75°的高角度缝为主,缝密度1.22条/m(图 6~图 7)。
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图 6 轮古东气田奥陶系碳酸盐岩岩心照片a—AF127井,5569.8 m,O1-2y,泥晶灰岩,高角度构造缝,缝宽2~4 mm,沿缝部分充填方解石;b—AN631井,5791.5 m,O3t,亮晶生屑灰岩,二组构造缝斜交,沿裂缝溶蚀和充填,缝面见氧化边;c—AN62井,5782.3 m,O1-2y,颗粒灰岩,晚期水平裂缝切割早期缝合线,沿晚期裂缝部分溶蚀;d—AG392井,6264.5 m,O2y,藻粘结砂砾屑灰岩,高角度构造缝,半充填方解石,岩心上见构造缝不连续延伸;e—AN621井,5766.2 m,O3t,颗粒灰岩,早期缝合线被晚期高角度构造缝切割,半充填泥质;f—AG35井,6158.4 m,O3t,砂屑生屑灰岩,早期溶洞充填角砾与巨晶方解石,晚期裂缝切割早期裂缝,沿晚期裂缝扩溶;g—AN631井,5973.1 m,O1-2y,早期网状裂缝呈龟背状充填方解石,晚期沿部分宽缝充填泥质,岩心部分大理岩化;h—AG391井,5817.2 m,O3l,生物砾屑灰岩,生物为珊瑚和藻类,为洞穴充填角砾,砾间充填泥质;i-AG392井,6345.7 m,O1-2y,亮晶颗粒灰岩,缝合线发育Figure 6. Core photos of Ordovician carbonate rock in Lungudong gas fielda-Well AF127, 5569.8 m, O1-2y, cryptite, high angle structural fracture, width of fracture 2-4 m, partly filled with calcite along fractures; b-Well AN631, 5791.5 m, O3t, calcsparite bioclastic limestone, two groups of structural fractures obliquely crossing, corroded and filled along fractures, oxidation edge distributed in fracture panel; c-Well AN62, 5782.3 m, O1-2y, grained limestone, late period horizontal fractures cutting early stage furrow lines, partly corroded along late period fractures; d-Well AG392, 6264.5 m, O2y, algal bound gritty limestone, high angle structural fracture, half filled with calcite, structural fractures discontinuously extending in core; e-Well AN621, 5766.2 m, O3t, grained limestone, late period high angle structural fractures cuting early stage furrow lines, half filled with shale; f-Well AG35, 6158.4 m, O3t, gritty bioclastic limestone, early period limestone cave filled with rubble giant crystal calcite, late period fractures cutting early period fractures. corroded along late period fractures; g-Well AN631, 5973.1 m, O1-2y, early period calcite filling fractures like turtleback, late period part of broad fractures filled with shale, core partly marbleized; h-Well AG391, 5817.2 m, O3l, bioclastic calcirudite, bioclasts consisting of coral and algae, cave filled with rubble stone, shale filling inter gravel; i-Well AG392, 6345.7 m, O1-2y, calcsparite grained limestone, developing furrow lines![]()
图 7 轮古东气田奥陶系碳酸盐岩储层铸体薄片a—AN48井,5548.5 m,O2y,泥粉晶灰岩,构造缝交织分布,沿缝见扩溶现象,红色铸体;b—AN621井,5778.3 m,O1—2y,亮晶颗粒灰岩,压溶和溶蚀缝,红色铸体;c—AN14井,5335.6 m,O3l,泥粉晶灰岩,构造缝交织分布,红色铸体;d—AG18井,5540.2 m,O2y,粉晶灰岩,构造缝交织分布,红色铸体;e—AG39井,5832.5 m,O2y,泥—亮晶颗粒灰岩,沿构造缝扩溶后,部分方解石充填,红色铸体;f—AG391井,5810.1 m,O3l,泥—亮晶颗粒灰岩,压溶缝,红色铸体Figure 7. Cast slice of Ordovician carbonate reservoir in Lungudong gas fielda-Well AN48, 5548.5 m, O2y, powder micrite limestone, structural fractures interleave, expanded corrosion along fractures, red cast; b-Well AN621, 5778.3 m, O1–2y, calcsparite grained limestone, pre-solution and corroded fractures, red cast; c-Well AN14, 5335.6 m, O3l, powder micrite limestone, structural fractures interleave, red cast; d-Well AG18, 5540.2 m, O2y, crystal powder limestone, structural fractures interleave, red cast; e-Well AG39, 5832.5 m, O2y, micrite-calcsparite grained limestone, after expanding corrosion along fractures, partly filled with calcite, red cast; f-Well AG391, 5810.1 m, O3l, micrite-calcsparite grained limestone, pre-solved fractures, red cast根据形成机理,裂缝分为构造缝、压溶缝和溶蚀缝。构造缝约占区内裂缝总数的60%,缝宽一般小于5 mm,主要为剪切缝,其次为张性缝。构造缝以垂直缝最为发育,早期构造缝平行排列,局部呈枝叉状和雁行状,多数已被方解石、泥质和沥青质全充填或半充填,局部区域多期不同产状的裂缝相互交切形成网状裂缝。压溶缝是由沉积负荷引起的压实作用和压溶作用形成,主要表现为缝合线,产状多与层面平行,呈锯齿状和肠状弯曲延伸,常被泥、铁质半充填或全充填,约占裂缝总数的20%。溶蚀缝主要由地表水和地下水沿早期的裂缝系统溶蚀扩大产生,呈弯曲分布,延伸短,缝宽一般 > 1 mm,沿断裂面上生长晶形完好的方解石晶体或晶簇,约占裂缝总数的15%(图 6~图 7)。
2.3 成像测井裂缝特征
成像测井是识别井周裂缝发育条数、产状和有效性等的直接手段。构造缝形成后,在后期应力和溶蚀改造下,会不断改变赋存状态,其中多期应力的改造作用目前测井技术不能有效识别,后期溶蚀作用造成的裂缝形态变化则能较好地从井壁图像上识别并确定[14-15]。
利用工区完钻32口井的成像测井资料,成像测井可识别的裂缝主要为构造缝、溶蚀缝和钻井诱导缝。构造缝主要为构造应力成因,裂缝形态完整,轨迹闭合;溶蚀缝由后期扩溶作用形成,缝面基本闭合,多不完整,呈不规则扩溶特征;钻井诱导缝为人工裂缝,由钻具机械诱导和地层应力释放造成,多为无效裂缝(图 8)。
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图 8 轮古东气田奥陶系碳酸盐岩测井裂缝发育特征a、b、c、d—高角度构造窄裂缝,缝面形态基本完整,轨迹闭合;e、f、g、h—高角度构造窄裂缝,沿缝不规则扩溶;i、j、k、l—斜交羽状诱导微裂缝Figure 8. Ordovician carbonate logging fracture development characteristics in Lungudong gas fielda, b, c, d-High angle structural narrow fracture, fracture plane form is mostly intact, track closed; e, f, g, h-High angle structural narrow fracture, irregular broaden corrosion; i, j, k, l-Obliquely crossing pinnate lead tiny fracture平面上,工区裂缝以高角度(45°~75°)裂缝为主,走向以NE-SW为主。有效裂缝具有更强的岩石切割破坏能力,裂缝宽度和密度越大,取心收获率越低,裂缝有效性越好。纵向上,良里塔格组裂缝发育受岩性控制,裂缝发育密度与自然伽马值(泥质-泥灰质含量)成反比,自然伽马值增大,泥质-泥灰质含量增高,裂缝发育密度降低,良里塔格组内部自然伽马值从约11 API变化到60 API以上,泥质-泥灰质含量从5%上升至40%以上,当自然伽马值达到45 API,泥质-泥灰质含量超过30%时,裂缝不发育。良里塔格组裂缝平均4条/100 m,以不规则网状交切微细裂缝为主要特征,裂缝开度较小,少见大开度(窄缝以上)的构造缝,平均缝宽26.9μm,中缝及宽缝(石油行业标准SY/T 6286-1997)发育率6.9%。一间房和鹰山组岩性较纯,自然伽马值普遍低于25 API,平均约16.8 API,层组内泥质-泥灰质含量没有明显变化,泥质含量平均约2.3%。裂缝发育主要受断裂(应力强度)及构造控制,岩性控制不明显,裂缝发育程度高,开度相对较大,缝面溶蚀特征明显,一间房组14条/100 m,平均缝宽44.5μm,中缝及宽缝发育率9.1%;鹰山组6条/ 100 m,平均宽度37.5μm,中缝及宽缝发育率9.8%。
2.4 地震预测裂缝特征
裂缝的存在会造成地震波频率随方位角变化,在裂缝的法线方向,频率随方位角的衰减不同于裂缝的走向方向,地震波的衰减强度与裂缝的密度成正比,裂缝越发育,频率随方位角变化就越明显,频率椭圆扁率的大小代表了频率的各向异性强度,并且用这种强度来指示裂缝发育的强度。为得到准确的裂缝密度信息,多井结合约束裂缝密度发育门槛,利用研究区取心和成像测井对裂缝发育井和不发育井共同约束,得到最终的裂缝预测数据体并进行裂缝平面预测(图 9)。
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图 9 轮古东—一间房组FRS叠前裂缝预测与测井裂缝走向、密度叠合图Figure 9. Overlapping figure of Lungudong-Yijianfang Formation FRS pre-stack fracture forecasting and strike and density of logging fracture研究区一间房组裂缝最发育,利用成像测井资料约束,FRS叠前裂缝预测表明,现今最大水平主应力方向、裂缝走向、裂缝分布范围及发育密度主要受断裂控制。
现今最大水平主应力方向指示地层岩石所承受的最大应力方向,在同样的地层岩性、相似岩石机械强度条件下,走向平行于最大水平主应力方向的裂缝系统在力学上最容易保存,与之相交或垂直的裂缝则趋于闭合。轮古东气田成像测井解释仅AN171、AG38C井周边由于应力的复杂,裂缝走向与主应力走向存在较大夹角,其余区域裂缝走向与主应力走向基本一致,裂缝走向以NE-SW向为主,指示轮古东斜坡断裂系统更容易保持开启,也更容易获得高产。不同期次、走向的断裂控制的裂缝走向略有差异,南北向轮古东I号走滑断裂周边井裂缝走向主要为NE 30°~50°;北东向走滑断裂周边井裂缝走向主要为NE 30°~80°。
平面上,裂缝主要分布在断裂周围1 km范围内,成像测井及FRS叠前裂缝预测表明,随着井点距断裂距离增大,裂缝发育强度(裂缝线密度)呈指数降低,当井点距断裂距离 < 0.25 km,裂缝发育密度快速增加,当井点距断裂距离 > 1 km,裂缝发育差或不发育(图 9,图 10),与塔里木盆地西北缘柯坪—巴楚露头区多条走滑断裂的调查结论类似,即随着距断裂距离的增大,断裂控制的裂缝密度与距断裂距离呈指数递减关系[8-9]。
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图 10 轮古东气田距走滑断裂距离与裂缝发育密度关系图Figure 10. The relationship between the distance by strike slip fault and fracture development density in Lungudong gas field3. 断裂破碎带结构及与油气关系
3.1 断裂破碎带结构
走滑断裂构造样式,一般由一系列产状陡倾的大型-巨型平移断层及其间的断夹块体组成,平面上表现为雁列式、斜列式或帚状构造样式,在剖面上表现为陡立的断层带或断夹块的相间排列[16-19]。由于力学机制复杂,走滑断裂构造样式的差异造成走滑断裂破碎带在三维空间具有复杂的结构,对断裂破碎带组合方式的刻画对储层与油气运聚关系密切[8-11, 16-19]。针对研究区气藏特征,以主干走滑断裂为主线,以次级和微断裂为骨架,以裂缝为脉络,将研究区断裂破碎带平面上划分为“羽状破碎带、转换破碎带、斜列破碎带、复合破碎带”4种组合模式(图 11)。
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图 11 轮古东气田断裂破碎带结构Figure 11. The structure of fault crushed zone in Lungudong gas field“羽状破碎带”指次级和微断裂发育,储层沿破碎带呈散开状发育,剖面上为正花状断裂,平面上次级裂缝沿主干断裂呈羽状分布。羽状破碎带为有利的储层发育区,轮古东目前AG341、AG353、AG391C等高产井钻探区域为羽状破碎带。AG391井钻探断裂下盘的羽状破碎带,取心和成像测井证实,鹰山组发育II类裂缝孔洞型储层51.5 m/8层,平均孔隙度2.83%;III类孔洞型储层13 m/1层,孔隙度1.8%。鹰山组裂缝发育,为高角度的窄缝,以构造剪切缝为主,底部存在少量的构造张性缝,且沿裂缝有扩溶作用,该井累产油0.16×104 t,累产气0.25×108 m3;AG391C井钻探临近的断裂上盘的羽状破碎带,效果要好于AG391井,目前已累产油0.55×104 t,累产气0.61×108 m3,一方面表明羽状破碎带局部构造高点油气更为富集;另一方也证实,羽状破碎带内部结构复杂,断裂上盘和下盘之间存在油气的侧向封堵。目前塔里木盆地塔中I号气田Z15井区已通过水平井穿主干断裂钻探羽状破碎带的多个串珠集合体,完钻13井取得预期效果,已建成黑油年产能25×104 t[2]。
“转换破碎带”指走滑断裂转换部位,应力从一条断层逐渐转至另一条断层,特定部位同时发育两条走滑断裂,裂缝主要发育于两断层叠置的转换破碎带内。研究区仅AG39井发育,剖面上为正花状断裂,平面上轮东1号断裂AG39构造分段转换形成局部构造,主要的构造变形层系位于中上奥陶统,石炭系地层无明显的构造变形,上奥陶统良里塔格组地层厚度没有明显变化。AG39井钻探构造高点,实钻证实储层发育,上奥陶统良里塔格组与下奥陶鹰山组均发育储层且测试均获得高产,成相测井解释储层以裂缝孔洞型储层为主,II类储层2.5 m/1层,孔隙度3%,III类储层66.5 m/7层,平均孔隙度1.63%,裂缝主要集中发育于良里塔格组表层,以构造张性缝为主,扩溶现象明显,裂缝走向为东西向,应力走向为北东向,与裂缝走向存在40°夹角。该井良里塔格试采,已累产油0.94×104 t,累产气1.32×108 m3。
“斜列破碎带”指裂缝在主干和次级断裂集中发育,储层沿走滑断裂呈线性分布,剖面上次级断裂与主干断裂近平行排列,呈近直立状,平面上次级断裂和裂缝分布于主干断裂的二侧,呈大角度斜交。目前轮古东区块仅轮古35-1钻遇该破碎带,测井解释II类储层4.5 m/1层,孔隙度2.7%;III类储层36 m/5层,平均孔隙度1.72%。由于该井井下落鱼未能投产,产能情况有待后续评价。
“复合破碎带”指走滑断裂和逆冲断裂相互作用,裂缝在断裂交汇部位集中发育。研究区仅发育在桑塔木断垒带东部,由于东西向的逆断裂形成于海西期,控制了桑南断垒带的构造形态,构造高部位裂缝发育且断裂的多期活动,油气多期充注与调整,该区为复式油气聚集区,已经在奥陶系、石炭系和三叠系多个层段获得工业产能,建成黑油年产能规模30万t[13]。奥陶系碳酸盐岩以裂缝孔洞型储层为主,除个别井分析困难外,近20多年的开发已基本证实,构造高部位整体连通。
3.2 断裂破碎带与油气关系
轮古东奥陶系碳酸盐岩凝析气藏优质储层的发育主要受控于岩溶作用与断裂活动,羽状破碎带以高角度断裂及伴生微裂缝发育为主,多期多组断裂裂缝叠加,是岩溶储层发育最有利部位,分布面积最广,是油气最富集的区域。
在加里东晚期,轮古东东倾斜坡形成,顺层岩溶开始发育;晚加里东末期—早海西期的地层抬升过程中,构造运动产生了大量裂缝,部分裂缝沟通地表水,顺层溶蚀形成大量次生溶蚀孔、洞和缝;在海西末期—印支初期的第二次抬升中,断裂活动形成的众多断裂及伴生裂缝,可能会使早期充填的裂缝重新开启,对储集体的改造起重要作用;燕山—喜山期,轮古东内幕储层被迅速埋藏,从中生代晚期开始的有机质热演化所产生的酸性水沿裂隙渗入,内幕原有的孔、洞、缝发生扩溶。可见,加里东期地层短期暴露,加里东期走滑断裂及其破碎带是岩溶作用的先期通道,增加了地表水及地下水与碳酸盐岩的接触面积和溶蚀范围,甚至在碳酸盐岩内部形成一个连续的淡水溶蚀系统,再加之海西期构造运动使部分裂缝开启,极大的改善了碳酸盐岩的渗滤能力[20-21]。
轮古东气田天然气主要来源于寒武系,原油主要来源于中-上奥陶统[13]。“十五”以来,中石油塔里木油田分公司针对奥陶系碳酸盐岩的科技攻关及勘探开发实践已经证实,油气的远距离和超远距离及水平运聚难度较大,主要以“原地垂向立体网状运移”为主要特征。轮古东走滑断裂及其破碎带以高角度断裂为主,沟通下部烃源岩,是油气运移的主要输导体系。由于断裂的多期活动和断层性质的相互转化,轮古东走滑断裂附近集中了未饱和凝析气藏并控制了垂向上含气饱和度的变化,天然气晚期充注时,沿断裂向上运移的大量天然气的气侵作用造成油气相态分异,从而造成轮古东现今油气分布状况,即以轻质油和天然气为主,局部缝洞体中含有早期充注的中质和重质原油。中质和重质原油主要分布于北西向次级走滑断裂及伴生裂缝不发育且晚期气侵作用较弱区域。此外,盖层控制了轮古东气田相态的保存,轮古东地区上奥陶统桑塔木组泥岩横向分布稳定,纵向上分布较集中,厚度490~660 m,且岩性致密,垂向断层对气藏的破坏作用较弱,封隔条件较好,是中下奥陶统储层的良好盖层。
4. 结论
(1)轮古东气田主干断裂分3期4组。第一期为中晚加里东期近北东、北西向走滑断裂;第二期为晚海西期近东西向逆冲断裂;第三期为喜山期近南北、北东向走滑断裂。
(2)裂缝主要为高角度(45°~75°)构造窄裂缝,沿缝存在溶蚀,走向主要为NE-SW。纵向上,裂缝发育密度与自然伽马值(泥质-泥灰质含量)成反比,一间房组裂缝发育密度最大(14条/100 m),其次为鹰山组(6条/100 m)和良里塔格组(4条/100 m);平面上,裂缝主要分布在主干断裂周边1 km范围内,随着距断裂距离增大,裂缝发育强度(裂缝线密度)呈指数降低。
(3)断裂破碎带平面上划分为“羽状破碎带、转换破碎带、斜列破碎带、复合破碎带”4种结构。走滑断裂及其破碎带是油气的主要输导体系,控制了油气的富集与油气相态的分异,羽状破碎带分布面积广,是油气最富集的区域。
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图 1 大兴安岭南段大地构造位置图(a)(据吴福元等,2007修改)及岩浆分布与矿产资源略图(b)(据张兴洲等,2012修改)
1—中—新生代地层;2—晚古生代地层;3—早燕山期花岗岩;4—海西期花岗岩;5—早古生代花岗岩;6—晚燕山期花岗岩;7—Pb-Zn矿床及编号;8-Fe-Sn矿床及编号;9—Cu-Mo矿床及编号;10—断层;11—罕苏木;12—研究区位置;13—地名;14—国境线;15—断裂(F1—塔源—喜桂图断裂;F2—贺根山—黑河断裂;F3—西拉木伦—长春断裂;F4—伊通—依兰断裂;F5-牡丹江断裂;F6—敦化—密山断裂)区域典型矿床:①—敖仑花;②—半拉山;③—羊场;④-老架构;⑤—闹牛山;⑥—莲花山;⑦—龙头山;⑧—蒙恩陶勒盖;⑨—布敦化;⑩—敖尔盖;⑪—大井;⑫—黄岗;⑬—白音诺尔;⑭—毛登;⑮—宝盖沟;⑯—查木汗;⑰—浩布高;⑱—敖瑙达巴;⑲—拜仁达坝;⑳—维拉斯托
Figure 1. Tectonic location (a) (modified from Wu et al., 2007) and geological map showing distribution of magmatic rocks and mineral resources (b) (modified from Zhang et al., 2012)
1-Middle-Cenozoic; 2-Late Paleozoic; 3-Early Yanshan granite; 4-Hercynian granite; 5-Early Paleozoic granite; 6-Late Yanshan granite; 7-PbZn deposits and numbers; 8-Fe-Sn deposits and numbers; 9-Cu-Mo deposits and numbers; 10-fault; 11-Hansumu; 12-Research area; 13-Place name; 14-Border line; 15-Fracture(F1-Tayuan-Xiguitu fracture; F2-Hegenshan-Heihe fracture; F3-Xilamulun-Changchun fracture; F4-YitongYilan fracture; F5-Mudanjiang fracture; F6-Dunhua-Mishan fracture)Typical regional deposits: ①-Aolunhua; ②-Banlashan; ③-Yangchang; ④-Laojiagou; ⑤-Naoniushan; ⑥-Lianhuashan; ⑦-Longtoushan; ⑧-Mengentaolegai; ⑨-Budunhua; ⑩-Aoergai; ⑪-Dajing; ⑫-Huanggang; ⑬-Baiyinnuoer; ⑭-Maodeng; ⑮-Baogaigou; ⑯-Chamuhan; ⑰-Haobugao; ⑱-Aonaodaba; ⑲-Bairendaba; ⑳-Weilasituo
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图 2 研究区地质简图
1—全新统冲洪积层; 2—中二叠统大石寨组; 3—中二叠统哲斯组; 4—早白垩世二长花岗岩; 5—石英脉; 6—采样位置; 7—地名
Figure 2. Simplified geological map of the study area
1-Holocene alluvial layer; 2-Middle Permian Dashizhai Formation; 3-Middle Permian Zhesi Formation; 4-Early Cretaceous monzonitic granite; 5-Quartz veins; 6-Sample location; 7-Place name
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图 3 二长花岗岩野外露头(a、b)和镜下照片(c、d)
Pl—斜长石;Kfs—钾长石;Qtz—石英;Bt—黑云母;Hbl—角闪石
Figure 3. Outcrop(a、b)and micrographs(c、d)of monzonitic granite
P1-Plagioclase; Kfs-Potash feldspar; Qtz-Quartz; Bt-Biotite; Hbl-Common hornblende
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图 4 二长花岗岩锆石阴极发光(CL)图像及测点年龄
Figure 4. Ages and CL images of zircons from the monzonitic granite
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图 5 二长花岗岩锆石U-Pb谐和图及206Pb/238U年龄
Figure 5. Concordia diagram and 206Pb/238Uages of zircon in monzonitic granite
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图 6 二长花岗岩Hf同位素特征(据Yang et al., 2006)
Figure 6. Hf isotopic compositions of monzonitic granite(after Yang et al., 2006)
表 1 二长花岗岩LA-MC-ICP-MS锆石U-Pb同位素分析结果
Table 1 LA-MC-ICP-MS zircon U-Pb analytical results of monzonitic granite
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