Paleomagnetism of late Cretaceous dykes in the Gangdese belt: New constraints on the position and structure of the southern margin of Asia prior to the India-Asia collision

This paper report paleomagnetic data from late Cretaceous diorite dykes that sub-vertically intrude granodiorites in the eastern Gangdese belt near the city of Lhasa.Our research goals are to provide further constraints on pre-collisional structure of the southern margin of Asia and the onset of the India-Asia collision.Magnetite is identified as the main magnetic carrier in our study.The magnetite shows no evidence of metamorphism or alteration as determined from optical and scanning electron microscope observations.A strong mineral orientation is revealed by anisotropy of magnetic susceptibility analysis both for the intruded dykes and the country rocks.The authors interpret this AMS fabric to have formed during intrusion rather than deformation.Fifteen of 23 sites yield acceptable site mean characteristic remanences with dual polarities.A scatter analysis of the virtual geomagnetic poles suggests that the mean result adequately averaged paleosecular variation.The paleomagnetic pole from the Gangdese dykes yields a paleolatitude of 14.3°N±5.8°N for the southern margin of Asia near Lhasa.The paleolatitude corresponds to an in-between position of the Lhasa terrane during about 130‒60 Ma.Furthermore,the mean declination of the characteristic remanent magnetization reveals a significant counterclockwise rotation of 18°±9°for the sampling location since about 83 Ma.In the light of tectonic setting of the dykes,the strike of the southern margin of Asia near Lhasa is restored to trend approximately about 310°,which is compatible with the hypothesis that the southern margin of Eurasia had a quasi-linear structure prior to its collision with India.

南黄海SYS90-1A孔第四纪沉积物磁性地层学研究

可靠的年代地层框架是开展南黄海地区第四纪环境演变研究的基础。目前南黄海南部地区缺乏可靠年代学控制的长序列钻孔。通过对南黄海南部SYS90-1A孔(孔深90.1 m)沉积物开展详细的磁性地层学研究,并结合AMS14C测年结果及区域已有磁性地层学结果,建立南黄海南部地区第四纪沉积物年代地层框架。结果显示,SYS90-1A孔岩芯记录了从布容(Brunhes)正极性时至松山(Matuyama)负极性时上部,包括Kamikatsura和Santa Rosa地磁漂移事件。早、中更新世界线即布容正极性时与松山负极性时界线(B/M界线)深度位于74.2 m,Kamikatsura和Santa Rosa地磁漂移事件深度分别位于79.75~82.47 m和85.25~87.74 m。根据Kamikatsura和Santa Rosa地磁漂移事件的年代控制点和平均沉积速率,推算钻孔底部年龄为0.96 Ma。南黄海SYS90-1A孔早更新世晚期的沉积速率约为8.66 cm/ka,中更新世以来的沉积速率约为9.5 cm/ka,而全新世以来的沉积速率为12.8 cm/ka,沉积速率自早更新世晚期以来呈增加趋势。这一结果不仅为南黄海南部第四纪沉积物研究提供了有效的年代学约束,而且为南黄海地区第四纪地层划分和对比、沉积环境与气候变化、物源示踪等研究提供了重要的时间标尺。

山东胶莱盆地五莲地区早白垩世红层古地磁研究及其构造意义

胶东半岛中生代以来的旋转变形对限定郯庐断裂的剪切走滑活动具有重要意义,然而目前对胶莱盆地中生代旋转变形与否及其幅度仍存在很大争议。本文选择胶莱盆地南部五莲地区早白垩世莱阳群龙旺庄组红层开展系统古地磁学研究,共采集11个采点82个定向古地磁岩芯样品。岩石磁学实验结果表明,样品的载磁矿物主要为赤铁矿,部分样品同时含有少量磁黄铁矿和磁铁矿;系统热退磁实验共分离出8个采点58个样品的稳定特征剩磁方向,并认为其可能代表岩石沉积时期的原生剩磁方向。8个采点的特征剩磁方向平均值为Ds=169.5°、Is=33.2°、ks=40.9、α_(95)=8.8。相对于稳定东亚极,五莲地区发生了显著的(22.8°±8.8°)逆时针旋转变形。结合前人在胶莱盆地白垩纪沉积岩中获得的古地磁结果,指示胶莱盆地晚白垩世以来可能经历了整体的逆时针(10°~20°)旋转变形,而沿五莲断裂带向南西方向的逆时针旋转变形幅度增大,表明受郯庐断裂带左行走滑的影响增强。此外,沿郯庐断裂带不同部位在不同时期发生了不同方式和幅度的旋转变形,其不仅受郯庐断裂带左行剪切活动影响,还与断裂带周缘不同地体的性质及其所处的大地构造背景有关。

Paleomagnetism of Early Tertiary volcanics in the South Shetland Islands and its tectonic implications

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Paleomagnetism of Cretaceous Red beds from Eastern Part of South China Block

We performed on paleomagnetic investigation of the Upper Cretaceous red sandstones collected from Fujiau and Guangdong provinces. Significant characteristic directions were isolated by principal comPonent analysis from 22 of 25 and 9 of 14 sampling sites iu Fujian and Guangdong,respectively. Maximum concentration of global mean directions every province is achieved at 70 %and complete (100 % ) untilting for Fujian and Guangdong, respectively. We regarded these mean directions as the Late Cretaceous paleomagnetic directions and calculated virtual geomagnetic poles (VGPs); Fujian, Lat. /Lon. = 79. 4°N/210. 3°E (α95= 5. 1°) and Guangdong, Lat. /Lon. = 80. 1°N/193. 4°E (α95=8. 0°). These two VGPs are nearly equal to each other and to a mean VGP from Sichuan Province reported previously. This observation suggests no relative movement among three regions, Fujian, Guangdong and Sichuan, since the Late Cretaceous. Two VGPs from this study are significantly different from previously reported VGPs from the same regions. Further systematic paleomagnetic works are needed to clarify this difference of VGP Positions.

Avalonia,get bent!–Paleomagnetism from SW Iberia confirms the Greater Cantabrian Orocline

The amalgamation of Pangea formed the contorted Variscan-Alleghanian orogen,suturing Gondwana and Laurussia during the Carboniferous.From all swirls of this orogen,a double curve in Iberia stands out,the coupled Cantabrian Orocline and Central Iberian curve.The Cantabrian Orocline formed at ca.315–290 Ma subsequent to the Variscan orogeny.The formation mechanism of the Cantabrian Orocline is disputed,the most commonly proposed mechanisms include either(1)that south-westernmost Iberia would be an Avalonian(Laurussian)indenter or(2)that the stress field changed,buckling the orogen.In contrast,the geometry and kinematics of the Central Iberian curve are largely unknown.Whereas some authors defend both curvatures are genetically linked,others support they are distinct and formed at different times.Such uncertainty adds an extra layer of complexity to our understanding of the final stages of Pangea’s amalgamation.To solve these issues,we study the late Carboniferous–early Permian vertical-axis rotations of SW Iberia with paleomagnetism.Our results show up to 70counterclockwise vertical-axis rotations during late Carboniferous times,concurring with the anticipated kinematics if SW Iberia was part of the southern limb of the Cantabrian Orocline.Our results do not allow the necessary penecontemporaneous clockwise rotations in Central Iberia to support a concomitant formation of both Cantabrian and Central Iberian curvature.The coherent rotation of both Gondwanan and Avalonian pieces of SW Iberia discards the Laurussian indenter hypothesis as a formation mechanism of the Cantabrian Orocline and confirms the Greater Cantabrian Orocline hypothesis.The Greater Cantabrian Orocline likely formed as a consequence of a change in the stress field during the late Carboniferous and extended beyond the Rheic Ocean suture affecting the margins of both Laurussia and Gondwana.

Phanerozoic Paleomagnetism Characteristics of the Qomolangma Area in Tibet

This paper conducts systematic test research on the 2920 paleomagnetic directional samples taken from Ordovician-Paleogene sedimentary formation in the north slope of Qomolangma in south of Tibet and obtains the primary remanent magnetization component and counts the new data of paleomagnetism the times. Based on the characteristic remanent magnetization component, it calculates the geomagnetic pole position and latitude value of Himalaya block in Ordovician-Paleogene. According to the new data of paleomagnetism, it draws the palaeomagnetic polar wander curve and palaeolatitude change curve of the north slope of Qomolangma in Ordovician-Paleogene. It also makes a preliminary discussion to the structure evolution history and relative movement of Himalaya bloc. The research results show that many clockwise rotation movements had occurred to the Himalaya block in northern slope of Qomolangmain the process of northward drifting in the phanerozoic eon. In Ordovician-late Cretaceous, there the movement of about 20.0° clockwise rotation occurred in the process of northward drifting. However, 0.4° counterclockwise rotation occurred from the end of late Devonian epoch to the beginning of early carboniferous epoch; 6.0° and 8.0° counterclockwise rotation occurred in carboniferous period and early Triassic epoch respectively, which might be related with the tension crack of continental rift valley from late Devonian period to the beginning of early carboniferous epoch, carboniferous period and early Triassic epoch. From the Eocene epoch to Pliocene epoch, the Himalaya block generated about 28.0° clockwise while drifting northward with a relatively rapid speed. This was the result that since the Eocene epoch, due to the continuous expansion of mid-ocean ridge of the India Ocean, the neo-Tethys with the Yarlung Zangbo River as the main ocean basin closed to form orogenic movement and the strong continent-continent collision orogenic movement of the east and west Himalayas generated clockwise movement in the mid-Himalaya area. According to the calculation of palaeolatitude data, the Himalaya continent-continent collusion orogenic movement since the Eocene epoch caused the crustal structure in Indian Plate-Himalaya folded structural belt-Lhasa block to shorten by at least 1000 km. The systematic research on the paleomagnetism of Qomolangma area in the phanerozoic eon provides a scientific basis to further research the evolution of Gondwanaland, formation and extinction history of paleo-Tethys Ocean and uplift mechanism of the Qinghai-Tibet Plateau.

Magnetic Fabrics and Paleomagnetism on Mesozoic Dike Swarms from Sao Sebastiao and Ubatuba Regions,NE Sao Paulo State,SE Brazil

The Mesozoic magmatism in Southern Brazil is represented mainly by the basaltic flows of the Serra Geral Formation,the tholeiitic dikes swarms from the Ponta Grossa Arch,Florianópolis,and along the coast

Minto Large Igneous Province: A 2.00 Ga Mafic Magmatic Event in the Eastern Superior Craton Based on U-Pb Baddeleyite Geochronology and Paleomagnetism

A precise U-Pb baddeleyite age of 1999±2 Ma has been obtained for the NNW trending Lac Shpogan dyke swarm of the James Bay area of the eastern Superior craton.Previously the age of the swarm was

Paleomagnetism of Metamorphosed Sudbury Dykes, Canada: Relevance to a Theory of Crustal Shortening across the Grenville Collisional Orogen

The 1.235 Ga ESE-trending Sudbury dyke swarm cuts Paleoproterozoic to Archean rocks,but at its SE end becomes deformed and metamorphosed by the^1 Ga Grenville orogen,a result of collision between

PALEOMAGNETISM OF THE LATE CRETACEOUS AND EARLY TERTIARY ROCKS FROM FILDES PENINSULA,WEST ANTARCTICA, AND ITS GEOTECTONIC SIGNIFICANCE

The paleomagnetis m of 109 oriented samples collected from drill cores through 5 rock units of Late Cretaceous and Early Tertiary on Fildes Peninsula were systematically studied. According to the study, the paleomagnetic pole position of this area is different from the position of Australia during the 55-45 Ma period. This means that when the break-up of the Gondwanaland at 55-45 Ma ago, Australia was separated from the Gondwanaland, drifting southward 20°-30°Lat. and rotating 70°-80°westward and then gradually arriving at recent position. The paleolatitudinal data indicate that it is not impossible that the area studied was covered with land glacier at that time. The apparent polar wander path of Antarctica through the geological time are also roughly worked out.

A Preliminary Study on Paleomagnetism and Rock Magnetism of Eclogite from the Maobei Area

A preliminary study of paleomagnetism and rock magnetism has been done on 55 eclogite samples collected from the Chinese Continental Scientific Drilling (CCSD) site at the Maobei (毛北) area, Donghai (东海) County, Jiangsu (江苏) Province. Also the isothermal remanence, hysteresis loop, magnetic fabric, thermal susceptibility were measured, and analyses were made by electron-probe and scanning electric microscope on some samples synchronously. The result indicates that there are two groups of stable remanence, the normal and reversed magnetization. The remanence orientations are: D=94.3o, I=-29.1o and D=273.7o, I=15.4o, respectively. The magnetization intensity and the density of the samples which carry the normal magnetization are very different from those bearing reversed magnetization. The magnetic anisotropy is weak, and the minimum axis is hardly determined. The isothermal remanence and the hysteresis loop show that the magnetic carriers of the eclogite are likely SD (single domain) and PSD (pseudo-single domain) magnetite. According to the magnetic property, the cause of formation of magnetic carriers, the mechanism of the remanence, and the significance for the tectonics are discussed.

扬子板块、澳大利亚板块、印度板块在新元古代晚期(750~540 Ma)古板块再造:来自古地磁制约

扬子板块在新元古代时期作为Rodinia超大陆的重要组成部分,其位置一直存在争议。为探讨扬子板块在新元古代晚期的位置,综合前人发表过的古地磁数据,利用古地磁研究方法,对扬子板块与澳大利亚板块、印度板块在新元古代晚期的相对位置关系进行研究。根据地层对比、锆石测年等诸多证据,将扬子板块置于印度板块北缘(现今位置)、澳大利亚板块西北缘(现今位置)。基于扬子、印度、澳大利亚运动学特征分析,认为扬子板块在Rodinia超大陆裂解时运动至高纬度地区,750~635 Ma期间,扬子板块处于中高纬度地区,在635 Ma时开始快速向低纬度地区运动。虽然将扬子置于印度北缘,但认为二者并不相连,而是到了570 Ma左右发生碰撞后连接到一起,并一同加入冈瓦纳大陆。

西安凹陷 f12 地裂缝发育区第四系及裂缝沉降特征

在西安凹陷南缘清凉山地裂缝f12两侧钻取了两口超过400 m的全取芯井,笔者对DZ1井(420 m)和DZ2井(400.5 m)岩心作了沉积学分析,进行了古地磁、磁化率及粒度测量,分析了地裂缝沉降特征。结果表明:DZ1孔岩心包括0~93 m黄土–古土壤序列沉积L2~S11,缺失上部马兰黄土及S1,93 m以下为三门组河湖相沉积。DZ2钻孔岩心包括0~72 m黄土–古土壤S1~S9序列沉积,缺失上部黑垆土S0和马兰黄土L1,73 m以下为三门组河湖相沉积。DZ1孔岩心和DZ2孔岩心的黄土地层层序基本一致,包括中更新世离石黄土上部及早更新世离石黄土下部,未见午城黄土。河湖相三门组与午城黄土同时异相,在两口井都持续沉积至第四纪底界,并穿时至上新世顶部。两口井岩心均记录了B/M界限,J、O、R极性亚带及M/G界限,这些界线为两口井的地层对比提供了科学依据。其标志层粉砂质黄土层L9位置高差为5 m,古地磁B/M界线位置高差为4 m,J亚带位置高差为8~17 m,O亚带位置高差为31~22 m,R亚带位置高差为56~47 m,M/G界线位置高差为54 m。总体看来,DZ1孔地层界线和古地磁界线高程都较DZ2孔低,并且越靠下层差距越大。根据地层高差及古地磁界线高差判断,地裂缝f12上盘相对下降4~54 m。在DZ1孔373.6 m处发现次裂缝面,经计算裂缝面倾向南东,倾角为77°。研究成果为进一步认识西安凹陷沉积环境,地裂缝特征及对西安地区防控地裂缝地质灾害具有重要意义。

四川LZ页岩储层现今地应力方向及主控因素——以龙一段为例

现今地应力场方向是影响页岩储层压裂改造效果的主要因素之一,进行现今应力场方向展布特征及其主要影响因素分析对页岩气开发应用具有重要的意义。利用古地磁结合波速各向异性法、微地震监测法、测井资料3种方法来判别地应力方向,对LZ地区地应力方向平面展布特征及主控因素分析。结果表明:宽缓向斜处3种解释方法都适用,准确度和可信度排序为岩心实验测试、偶极横波测井、电成像测井。断裂影响区域偶极横波测井不再适用,岩心实验测试结果可信度大于电成像测井。裂缝发育强构造变形区域对3种方法解释结果均有影响,需多种方法结合分析;LZ地区龙马溪组现今最大主应力方向变化范围在90°~125°。得胜、宝藏、云锦向斜的最大主应力方向在约115°,福集向斜最大水平主应力方向偏转最大,在80°~100°,可能与西侧华蓥山断裂逆冲兼具走滑有一定关系。断裂规模越大其扰动范围和强度越大。Ⅰ、Ⅱ、Ⅲ、Ⅳ级断裂最大扰动范围分别为1100、850、500、300 m。紧闭背斜褶皱变形区,受褶皱顶部派生的拉张应力影响,地应力方向沿着褶皱轴向偏转,靠近褶皱顶部,受拉张应力影响大,偏转角度最大。研究成果可为后期水平井井位轨迹优化及压裂改造工程提供理论支撑。

青藏高原拉萨地块中部上三叠统多布日组沉积岩古地磁研究及其构造意义

拉萨地块晚古生代至早新生代期间的演化历史对理解青藏高原的形成和演化至关重要.本文报道了青藏高原中部申扎地区上三叠统多布日组沉积岩的古地磁学、岩石磁学和岩相学分析结果.岩石磁学结果显示红层、灰岩和灰绿色砂岩分别以赤铁矿,赤铁矿与磁铁矿,以及磁铁矿为主要载磁矿物.岩相学结果表明红层、灰岩和灰绿色砂岩中的磁性矿物主要为自生成因.对60个采点(602块样品)进行系统热退磁实验,结果揭示出多布日组沉积岩的特征剩磁方向在地理坐标系下为D_(g)=13.9°,I_(g)=38.9°(α_(95g)=0.9°),在地层坐标系下为D_(s)=16.7°,I_(s)=8.4°(α_(95s)=1.5°).进一步对其特征剩磁方向进行逐步褶皱展平检验,结果显示精度参数k的极大值在9.9%展平状态下最大,对应的特征剩磁方向为D=14.4°,I=35.9°(α_(95)=0.9°),古地磁极为72.9°N,216.2°E(dp=0.6°,dm=1°).这一古地磁极与拉萨地块54~47 Ma的古地磁极接近,表明其重磁化时间可能发生在54~47 Ma期间.结合前人获得的拉萨地块新生代早期古地磁数据以及同期的欧亚大陆古纬度数据,我们推断拉萨地块在56~44 Ma时相对欧亚大陆发生了1676±577 km的南北向构造缩短.

利用古地磁学方法恢复钻孔岩心原始方位可靠性的探讨:以塔里木盆地钻井为例

针对非定向钻孔岩心原始方位难以确定的科学问题,利用塔里木盆地5口钻井(TKQ101井、SHUN9井、TAT19井、TZ18井和TS108井)志留纪无定向砂岩样品,对典型样品进行了岩石磁学、扫描电镜(SEM)和能谱分析(EDS)等实验,明确了样品的主要载磁矿物,之后对43块样品进行了退磁处理,并分析了校正后的磁化率各向异性(AMS)最大轴(K_(max)轴)指示的古水流方向,探讨了利用剩磁恢复岩心原始方位的可靠性。AMS结果揭示的沉积组构支持整个钻孔回次地层近似水平;岩石磁学、SEM和EDS实验结果表明TKQ101井样品主要载磁矿物为磁铁矿、含有少量针铁矿和赤铁矿,其他钻井样品主要载磁矿物为磁黄铁矿和磁铁矿。43块样品的系统退磁实验结果显示,TKQ101井岩心样品可分离出可靠的现代场黏滞剩磁方向(VRM)和志留纪地层原生剩磁方向(ChRM),经VRM和ChRM各自计算获得岩心原始方位旋转量(R,R′,其中R,R′分别为利用VRM和ChRM磁偏角获得的岩心原始方位旋转量)一致,校正后的K_(max)指示的古水流方向也与地质证据相吻合,支持TKQ101井岩心原始标志线方位需逆时针旋转258.0°~262.0°;其他4口钻井岩心退磁结果呈现单分量特征,综合分析明确其经历了由喜山期油气运移、聚集等流体活动导致的化学重磁化,携带的剩磁为现代地磁场的黏滞剩磁和喜山期重磁化成分叠加结果。通过校正后K_(max)轴指示的古水流方向和地质证据验证后,揭示利用VRM获得的恢复岩心原始方位旋转量R较为可靠。综上,钻井岩心原始方位恢复需要旋转的角度如下:TKQ101井岩心在逆时针旋转258.0°~262.0°后即可获得可靠的原始标志线方位;SHUN9井第4,5,6回次岩心标志线的方位需分别逆时针旋转148.1°,221.2°和318.2°;TAT19钻井第3,5回次岩心标志线的方位需分别逆时针旋转269.8°,155.9°;TS108井和TZ18井岩心标志线的方位需分别逆时针旋转239.3°,256.6°。

拉萨-羌塘地体碰撞时间新认识-来自羌塘盆地古地磁年代学的证据

青藏高原从北到南由松潘甘孜可可西里地体、羌塘地体和拉萨地体组成,上述地体的碰撞过程涉及到特提斯洋的开合演化和陆陆碰撞等科学问题。例如,班公湖-怒江特提斯洋的闭合以及青藏高原从洋盆抬升为陆地等的时间和过程,其中拉萨-羌塘地体的碰撞时间和过程尤为关键。在羌塘盆地北部,拉萨-羌塘地体的碰撞过程被雁石坪群上段的夏里组和索瓦组地层所记录,此前虽然我们建立了羌塘盆地雁石坪剖面夏里组和索瓦组的磁性地层,由于在上述两组地层中没有发现标准化石,故而不能通过古生物年代来约束其古地磁年代,这就限制了对上述科学问题的理解。最近,Yin(2016)根据菊石化石,给出了索瓦组较为可靠的古生物年代,也结束了索瓦组古生物年代的长期争议。这一成果,为我们给出夏里组和索瓦组的古地磁年代,提供了重要的古生物年代约束。鉴于此,本次研究重新梳理了夏里组和索瓦组的菊石、双壳、孢粉等古生物地层,重新厘定了夏里组和索瓦组的古生物年代,在此基础上约束出夏里组和索瓦组的古地磁年代,其年代分别为~164.0-160.2 Ma和160.2-156.8 Ma。除此之外,结合前人对上覆地层的U-Pb定年,揭示拉萨地体与羌塘地体的碰撞时间约为~156.8-154.9 Ma。

湖南茶陵盆地上白垩统戴家坪组红层的古地磁研究

由于红层能够携带稳定的天然剩磁,因此在古地磁研究中被广泛采用。以往对于红层的研究大多集中于河湖相,对风成相红层的研究较少,尤其是风成沉积过程及沉积环境对剩磁记录的影响仍缺乏清晰的认识。对湘东南茶陵盆地上白垩统戴家坪组红层开展了古地磁研究,通过对比分析研究了风成相和河湖相红层携带剩磁的稳定性及其剩磁记录的可靠性。岩石磁学结果显示载磁矿物为磁铁矿、磁赤铁矿、赤铁矿。退磁结果显示,仅有约1/6的样品能够分离出特征剩磁(ChRM)。虽然两者的ChRM平均方向总体一致(风成相样品磁偏角Ds=222.7°,磁倾角Is=-43.3°,Fish统计精度参数κ=5.9,95%置信区间的半顶角角度α_(95)=20.6°,数据量n=11;河湖相样品D_(s)=204.6°,I_(s)=-47.8°,κ=2.4,α_(95)=23.1°,n=28),但两者单个样品ChRM方向的分布均较为分散。岩石薄片分析表明,相较于河湖相红层而言,风成相样品以细颗粒为主,部分粒度较粗,几乎无填隙物,易于受到物理扰动和后期化学作用影响,使得其剩磁记录的稳定性变差。对取自同一前积纹层不同部位风成相红层样品的退磁结果分析表明,当前积纹层与层系界面夹角大于20°时,其剩磁记录受到沉积过程的影响显著。对华南白垩纪红层样品古地磁结果的统计分析表明,华南白垩纪风成相红层剩磁的稳定性和可靠性总体较弱,可能是由于其结构松散且赤铁矿含量少,既不利于原生剩磁的稳定获得,也易于受到后期化学作用的改造而影响其可靠性。研究结果为风成相红层剩磁记录的稳定性和可靠性研究及其在古地磁研究中的应用提供有利指导。

河北省唐山地区古滦河冲积扇第四纪以来演化与变迁

古滦河冲积扇研究的关注点更多在全新世,对其更新世的演化与变迁一直没有进行过系统研究。根据古滦河冲积扇上PZK10、PZK20钻孔的磁性地层学、年代地层学、沉积学、测井沉积学、岩芯色度分析等,对古滦河冲积平原的第四纪三维地质结构、冲积扇体的规模以及迁移规律进行综合研究,结果表明:PZK10孔揭露了上新世时沉积的巨厚洪积成因“泥包砾”地层,早更新世时发育两个冲积扇-湖相旋回,中更新世时发育辫状河沉积,晚更新世发育湖相、冲积扇相、辫状河相沉积。PZK20孔上新世沉积了一套巨厚“泥包砾”层,早更新世为扇前平原-辫状河相沉积,中更新世为辫状河-冲积扇相沉积,晚更新世为辫状河沉积。古滦河发育两期冲积扇,第一期为早更新世早期,在沙流河镇一带出山口形成的规模较大的冲积扇;第二期为早更新世中期,古滦河在现今丘庄水库一带发生分流,在丰润区一带出山口形成的冲积扇。中更新世,第一期冲积扇开始萎缩,第二期冲积扇继续发育,形成巨厚砾石层;晚更新世,古滦河在迁西县城以北发生袭夺,东流迁移出研究区,在西峡口进入迁安盆地,形成以西峡口为顶点的冲积扇。