长江口外泥沙向南输运速率的变化探讨——以朱家尖岛附近海域为例

采用浅地层剖面测量、沉积物柱样测年和海图水深计算对比相结合的方法,探讨位于长江入海泥沙向南输送通道上的朱家尖岛海域的泥质沉积速率的历史变化,并通过水文泥沙测量和沉积物取样分析寻找长江入海泥沙向南输送的佐证。结果表明:朱家尖岛海域全新世海平面上升以来泥质沉积厚度为5~20m,相当于沉积速率0.06~0.25cm/yr;1840~1960年区域平均沉积速率为1.4cm/yr,近60年沉积速率仅为此前120年沉积速率的一半左右。据此推断:全新世后期以来该海域泥质沉积速率先后经历了一个长期(千年尺度)缓慢的增大阶段和一个短期(年代尺度)迅速的减小阶段,与长江流域人类活动和河口湾充填作用共同造成的入海泥沙通量的总体变化趋势相吻合。     

全新世长江泥沙堆积的时空分布及通量估算

利用长江中下游、河口及口外、浙-闽沿岸陆架6个主要沉积盆地的40个晚第四纪钻孔及其年代学数据和长江口外、陆架的浅地层剖面,计算了全新世不同阶段各沉积盆地的沉积速率,并进行了近7 000年来泥沙堆积通量的估算。研究发现全新世早期距今10 000年至8 000年间长江口下切古河谷是长江泥沙的主要堆积中心,沉积速率可高达15m/ka。随着海平面上升,全新世中期长江中下游也成为长江泥沙的重要沉积盆地,其中江汉盆地的沉积速率可达10m/ka。近2 000年来,口外、陆架的堆积呈明显增加趋势,反映长江中下游盆地和河口可容空间日益减小。根据沉积速率估算,距今7 000年来长江中下游堆积泥沙约13 074×108 t,同期水下三角洲和陆架的泥沙堆积量约为9 470×108 t。研究还发现全新世以来有两个异常低沉积速率时期：距今8000-7 000年期间上述各沉积盆地沉积速率均显著低,未见长江泥沙的沉积中心; 距今4 000-2 000 年期间长江口呈现低沉积速率。 这两次异常的原因推测与海平面、气候波动事件密切相关。     

长江口水下三角洲沉积物粒度组成及其在减沙背景下的响应

近年来长江口水下三角洲对入海泥沙减少的响应问题越来越受到关注。通过分析长江水下三角洲百年沉积速率的分布特征及位于水下三角洲泥质沉积区不同位置4个浅孔的粒度、~(210)Pb和~(137)Cs数据,探讨其对流域入海水沙变化及水动力变化的响应。研究结果显示,1954年后长江口北支萎缩是导致CDZS10孔所在区域沉积物粒度较其他3孔明显粗的主要原因。而CDZS10孔沉积物上粗下细则是由20世纪80年代三峡蓄水后长江入海泥沙显著下降、海洋动力明显增强引起的。另外,北支萎缩及三峡水库调蓄作用导致泥质区南移,并向杭州湾和嵊泗列岛延伸发展。     

长江河口水下三角洲210Pb分布特征及其沉积速率

通过对长江水下三角洲采集的十个沉积物柱状样中的放射性核素210Pb分析得知,长江水下三角洲表层210Pb放射性比度在2.15~4.22 dpm·g-1之间,210Pb沉降通量在1.50~11.21 dpm·cm-2 yr-1之间,过剩210Pb总量在>48.29~>361.68 dpm·cm-2之间;210Pb沉降通量以及过剩210Pb总量均高于理论值,这表明在沉积物中存在210Pb的净输入和聚集。由210Pb放射性比度剖面所反映的沉积速率可知长江水下三角洲泥质沉积区沉积速率介于1.36~4.11 cm·yr-1之间;总体上呈现近岸沉积速率较低,沿31°N纬线向20 m等深线沉积速率升高的趋势,从122°15′E到122°30′E范围为长江水下三角洲的泥质沉积物堆积中心,其平均沉积速率为3.51 cm·yr-1。     

渤海湾西岸全新世沉积速率对河流供给的响应

渤海湾西岸由北向南获取了3个钻孔,以全新世海相岩心为研究对象,采用AMS14C(Accelerator Mass Spectrometry14C,加速器质谱14C)测年方法建立年代框架并计算平均沉积速率,结合沉积物粒度组成及沿岸古河流三角洲发育历史,探讨了沉积速率对沿岸河流供给变化的时空响应。结果表明,早全新世—中全新世初期(11~6ka),渤海湾西岸整体沉积速率偏低,仅0.03~0.07cm/a,沉积物粒度较粗;中全新世6.43~4.97ka cal BP期间,NP3孔平均沉积速率为0.60~0.93cm/a,高于同期沿岸南部的CH110孔和BT113孔。沉积物组成以粉砂为主,粘土含量低,向上逐渐变粗,具三角洲反粒序特征。该时段的高沉积速率系渤海湾西北岸对潮白河、永定河及滦河沉积物供给的响应;中全新世晚期3.68~2.67ka cal BP期间,BT113孔沉积速率为0.27~1.4cm/a,高于同期沿岸北部CH110孔和NP3孔,沉积物组成以粉砂为主,粘土含量较NP3孔高,向上逐渐变粗,具三角洲反粒序特征。该时段的高沉积速率系渤海湾西岸南部对黄河沉积物供给的响应;晚全新世2.29~0.24ka cal BP期间,沿岸中部CH110孔沉积速率为0.55~0.91cm/a,高于同期沿岸南部的BT113孔和北部的NP3孔,该高沉积速率为渤海湾西岸中部对黄河和海河供给沉积的先后响应。     

近百年来长江口外泥质区高分辨率的沉积记录及影响因素探讨

通过对长江口外泥质区ZM11柱样的粒度和常微量元素分析,结合210Pb年代测定,探讨了研究区近百年来的沉积历史及影响因素。研究表明,ZM11柱样1950年以来平均沉积速率约为2.5 cm/a;受长江深水航道建设以及水下三角洲前缘侵蚀的影响,近十年来ZM11柱样沉积速率仍然保持3 cm/a以上;46 cm处0.3 cm厚的细砂层记录了1998年特大洪水事件,1998—1999年前后ZM11柱样沉积厚度高达20 cm。ZM11柱样沉积物物质成分较为均一,以粉砂为主;近百年来粒度变化与大通站泥沙粒径变化趋势不尽相同,可能主要受水下三角洲沉积环境控制。元素分析结果表明ZM11柱样沉积物物源比较稳定,基本来自长江物质输入,影响岩芯沉积物元素含量变化的因素主要有沉积物粒度组成、长江碎屑物质输入、生物作用以及人类活动。     

长江口及邻近海域现代沉积速率及其对长江入海泥沙去向的指示意义

对长江口及附近海域的16根重力柱样进行了210Pb沉积速率测试, 结合以往成果, 揭示了该区现代沉积速率分布格局, 对其控制因素以及其对认识长江入海泥沙去向的指示意义进行了探讨.沉积速率最高值分布在南支口外、杭州湾口群岛北部的前三角洲地区, 最高可达6.3m/a, 总体上在3cm/a以上; 次高值分布在杭州湾北部, 约1.7~3.0cm/a, 南部略低, 约0.4~1.0cm/a; 长江口水下负地形北部海域存在小片沉积速率较高的区域, 最高值达2.58cm/a; 低值主要分布在苏北辐射沙洲、过渡沉积区以及浅海陆架的大片区域, 基本保持在1cm/a以下.研究表明, 长江泥沙出口门后主要在水下三角洲地区进行了堆积, 其次有相当部分在涨潮流顶托下进入杭州湾, 进入杭州湾南部的泥沙又在落潮流作用下经杭州湾南侧向舟山海域方向输运; 长江入海物质向外海的扩散基本被控制在123°E以西, 苏北辐射沙洲、过渡沉积区以及浅海陆架的大片区域缺乏现代长江物质供应; 长江悬浮泥沙对研究区东北部陆架区影响较小, 废黄河口被侵蚀物质和黄海悬浮物质为其较高沉积速率的主要贡献者.      

末次冰消期以来长江口沉积环境演化及沿岸流变化

长江口附近的沿岸流和水团变化对研究长江三角洲沉积物的“源-汇”机制具有重要意义.对HZK2孔沉积物的粒度、年龄和有孔虫分布特征进行了研究分析.结果表明:HZK2孔52.5 m以上有孔虫均有分布,底栖有孔虫丰度在12 m以上和26.0~52.5 m含量超过40枚/g,代表不同沿岸流和水团的有孔虫属种含量在垂向上呈现明显的分带性.HZK2孔全新世以来经历了河口湾和水下三角洲两大沉积体系,并在全新世早期发育潮流沙脊.末次冰消期,钻孔所在位置受长江冲淡水和苏北沿岸流共同影响.全新世早期,则受苏北沿岸流影响为主;在此之后,长江口冲淡水的作用减弱,苏北、黄海沿岸流影响较强.全新世中晚期,苏北沿岸流、长江冲淡水、江浙沿岸流和东海外海水团多种水体共同作用钻孔所在海域,全新世晚期长江冲淡水作用占绝对优势.      

江苏圆陀角附近潮滩沉积岩芯粒度变化及其环境意义

江苏圆陀角位于长江北支岸线与江苏海岸线的交汇处,发育了粉砂淤泥质海岸典型潮滩地貌,潮滩岩芯沉积物粒度变化记录了潮滩环境变化的信息。2007年在圆陀角附近潮滩采集了192cm长的柱状岩芯,对沉积物的粒度组成进行了分析,分析结果显示,砂质粉砂是主要的沉积类型,岩芯分为三部分,从下部向上,粗颗粒沉积组分减少,反映了采样点附近潮滩环境由潮滩中部向上部转化的过程。根据岩芯沉积物¹³⁷Cs的1963年和1986年两个蓄积峰值时标推算,1963年以来的平均沉积速率为2.3cm/a,1986年以来的平均沉积速率为1.6cm/a,1963～1986年之间的平均沉积速率达到2.9cm/a。沉积速率变化表明20世纪60年代以来伴随潮滩淤积增高,圆陀角附近潮滩沉积物的沉积速率下降,大体与辐射沙洲南翼淤积型潮滩淤积速率一致,小于长江口外的泥沙沉积速率。泥沙来源主要是苏北沿岸流携带的部分泥沙在圆陀角附近沉积,伴随研究区围垦活动向海推进,在长江北支口门北侧形成了大片的泥质潮滩和水下沙嘴。     

滹沱河河道剖面地层及其沉积年龄

对河北省藁城市滹沱河河道剖面(GCA)进行了地层岩性及沉积年龄的研究。根据剖面地层特征及年龄建立了晚更新世末期以来古河道剖面年代地层框架,并推算出各沉积阶段平均沉积速率,为滹沱河平原段古河道的沉积环境演化及河流沉积规律等研究提供详细可靠的时间标尺。研究结果表明该剖面揭露了距今约3万年以来的沉积地层。以埋深880cm处的不整合面为界,分为上下两段。上段地层为全新世以来的沉积物,地层底界年龄约为11.35ka,平均沉积速率为0.78mm/a;下段地层为晚更新世晚期的沉积物,平均沉积速率为0.30mm/a。两段地层之间存在约6ka的沉积间断,这一发现对于重建研究区古环境具有重要意义。     

粤西-琼东北近海沉积物的运移和沉积

为了深入认识珠江现代入海物质在粤西陆架随海流迁移扩散的路径和沉积中心,利用Gao-Collins方法分析了粤西-琼东北近海1 515个站位的粒径趋势,并用²¹⁰Pb法测定了8支柱样的现代沉积速率。结果表明,在粤西沿岸流和南海暖流这两个相向海流的共同作用下,珠江口外珠江来源的泥质沉积物的主体被限制在-50 m等深线以浅的内陆架。现代珠江入海物质能维持粤西陆架泥质沉积区0.1 cm/a左右的现代沉积速率。在川山群岛至海陵岛一带和琼州海峡东侧泥质区,分别受岛屿阻挡和逆时针中尺度涡旋的影响,形成了现代沉积中心。在沉积物不同粒级的来源和搬运方式存在差异的地方,粒径趋势分析结果可能主要反映的是粗颗粒沉积物的运移趋势,而非细颗粒沉积物的运移方向。     

长江口沉积物~(210)Pb分布及沉积环境解释

在长江河口潮滩、分流河道和水下三角洲共获得18个柱样,进行沉积学分析和210Pb测定,并对其中6根柱样进行137Cs测定。经研究发现,长江口外在水深25～30m,122°30′N,31°00′E附近存在一个泥质沉积中心,沉积速率达2.0～6.3cm/yr。另外,在潮滩和涨潮槽也获得较高沉积速率,其中南汇和横沙岛潮滩沉积速率(1.03～1.94cm/yr)高于崇明东滩(0.51～0.76cm/yr),涨潮槽沉积速率也达0.86cm/yr。此外,在石洞口、南汇、九段沙潮滩和三角洲前缘有部分柱样未获沉积速率,推测为沉积环境不稳定或沉积速率过快所致。     

Horizontal and vertical variations in sedimentation and resuspension rates in a stratifying lake – effects of internal seiches

The temporal and spatial variations in the rate of sedimentation and sediment resuspension in Lake Rehtijärvi (southern Finland) were studied by sediment traps deployed in the stratifying and non‐stratifying regions of the lake. Both the gross sedimentation rate and the resuspension rate recorded by near‐bottom traps were significantly higher in the stratifying region (>20 m depth) than in the shallow part of the lake (2 m depth). These rate changes were caused by temporarily elevated hypolimnetic resuspension rates exceeding 40 g dry weight m^?2 day^?1 in July 2005, whereas in the shallow station no such peak was observed and the resuspension rate remained below 30 g dry weight m^?2 day^?1 throughout the study. The elevated resuspension rate in the hypolimnion could not be attributed to surface wave action or sediment disturbance by fish, but was due to the occurrence of internal seiches. The seiche amplitude was on average the highest in July, although the wind velocities were low; this was because winds temporarily were blowing along the longitudinal axis of the lake. Due to the steep slopes, the sediments of Lake Rehtijärvi are prone to redistribution and sediment focusing towards the accumulation areas also affected trap catches in the deep stations.     

MIS 3以来浙江温瑞平原YQ0902孔古环境与古气候变化记录*

YQ0902孔位于浙江南部瓯江三角洲南侧温瑞平原上。沉积相、粒度分析以及AMS ¹4C测年数据表明,硬土层之下为海洋氧同位素3阶段(MIS 3）形成的潟湖相沉积,据此推测MIS 3高海平面至少达到现今海平面之下30m左右(未经构造升降和沉积物压实作用等影响的校正,下同）。硬土层的成土过程发生于MIS 2,其母质部分为MIS 3的潟湖沉积,部分为河漫滩沉积。硬土层之上是一套形成于全新世的海侵—海退旋回,与长江三角洲南翼前缘的沉积相组合类似。研究钻孔初始海泛面约形成于9 cal ka BP,推算当时的海平面约低于现今海平面25 m。中全新世最大海侵前后,东亚季风较强,通过径流或沿岸流输入本区的沉积物较充足,沉积速率较大。随着海平面相对稳定或略有下降,东亚季风减弱,可容空间减小,中晚全新世(5～2 cal ka BP）沉积速率较低。高分辨率的XRF岩心扫描获得的元素相对含量是古环境与古气候研究的重要指标,其中Cl/Ti、Fe/Ti值可分别作为海相性(与海洋联通程度）与东亚季风强弱的替代指标。     

Metal accumulation in surface salt marsh sediments of the Bay of Fundy,Canada

We measured the amount of arsenic, chromium, copper, lead, nickel, vanadium, and zinc accumulated over a five-year period from 1997 to 2002 in surface sediments of seven salt marshes along the New Brunswick coast of the Bay of Fundy, Canada. Study sites extended from outer to inner Bay, spanning a gradient in tidal range (6–12 m) and mean sediment deposition rate (0.27–1.76 cm yr⁻¹). In each study site, metal concentrations were measured in low and high marsh areas. Concentrations of chromium, nickel, and zinc appear to be within their natural range, while arsenic, lead, and vanadium are enriched in some sites. Calculated sediment metal loadings rates showed variability among marsh sites that closely followed sediment deposition patterns, suggesting sediment deposition rate is the driving factor of short-term metal accumulation in Fundy marshes. The value of salt marshes as a sink for metals may be enhanced by high sedimentation rates.     

Late Quaternary basin evolution of the Gulf of Corinth: Sequence stratigraphy, sedimentation, fault–slip and subsidence rates

The Gulf of Corinth is a graben, which has undergone extension during the Late Quaternary. The subsidence rate is rapid in the currently marine part whereas uplift now affects a large part of the initially subsiding area in the North Peloponnese. In this paper, we document the rates of subsidence/uplift and extension based on new subsurface data, including seismic data and long piston coring in the deepest part of the Gulf. Continuous seismic profiling data (air gun) have shown that four (at least) major oblique prograding sequences can be traced below the northern margin of the central Gulf of Corinth. These sequences have been developed successively during low sea level stands, suggesting continuous and gradual subsidence of the northern margin by 300 m during the Late Quaternary (last 250 ka). Subsidence rates of 0.7–1.0 m kyr^− 1 were calculated from the relative depth of successive topset to foreset transitions. The differential total vertical displacement between the northern and the southern margins of the Corinth graben is estimated at about 2.0–2.3 m kyr^− 1.

Sequence stratigraphic interpretation of seismic profiles from the basin suggests that the upper sediments (0.6 s twtt thick) in the depocenter were accumulated during the last 250 ka at a mean rate of 2.2–2.4 m kyr^− 1. Long piston coring in the central Gulf of Corinth basin enabled the recovery of lacustrine sediments, buried beneath 12–13.5 m of Holocene marine sediments. The lacustrine sequence consists of varve-like muddy layers interbedded with silty and fine sand turbidites. AMS dating determined the age of the marine–lacustrine interface (reflector Z) at about 13 ka BP. Maximum sedimentation rates of 2.4–2.9 m kyr^− 1 were calculated for the Holocene marine and the last glacial, lacustrine sequences, thus verifying the respective rates obtained by the sequence stratigraphic interpretation. Recent accumulation rates obtained by the ²¹⁰Pb-radiometric method on short sediment box cores coincide with the above sedimentation rates. Vertical fault slip rates were measured by using fault offsets of correlated reflector Z. The maximum subsidence rate of the depocenter (3.6 m kyr^− 1) exceeds the maximum sedimentation rate by 1.8 m kyr^− 1, which, consequently, corresponds to the rate of deepening of the basin's floor. The above rates indicate that the 2.2 km maximum sediment thickness as well as the 870 m maximum depth of the basin may have formed during the last 1 Ma, assuming uniform mean sedimentation rate throughout the evolution of the basin.     

渤海湾西岸现代岸线钻孔记录的全新世沉积环境与相对海面变化

以渤海湾西岸现代岸线附近的NP3、CH110和BT113三个钻孔全新世岩心为研究对象,采用沉积岩石学、AMS ¹⁴C(accelerator mass spectrometry ¹⁴C,加速器质谱¹⁴C)测年、微体生物聚类分析等方法精细判别沉积相,重建渤海湾西岸全新世沉积演化历史,并利用微体生物组合分带对水深变化的指示,定量讨论全新世相对海面变化。结果表明:渤海湾西岸全新世受海陆交互作用影响,经历了沼泽-潮滩-浅海-前三角洲-三角洲前缘-三角洲平原环境的演化过程。全新世初始阶段,研究区中部和北部发育沼泽环境,南部未见沉积,与上更新统河流相沉积呈不整合接触。全新世早期,研究区潮滩环境发育。潮滩层厚度约1 m,历时数百至1千余年。至7000 cal BP前后水深增大,研究区进入浅海环境。约6000 cal BP,沿岸南北两端先后进入三角洲过渡环境,中部三角洲环境约开始于1500 cal BP。渤海湾西岸地区全新世的环境演化同时记录了该地区的相对海面变化:约10000 cal BP前后,渤海湾相对海平面已接近21.3~20.4 m。约8000 cal BP,相对海平面介于18.6~17.0 m。约6000 cal BP时相对海平面低于6.8 m,5000~1000 cal BP,相对海平面高于-2.5 m,1000~800 cal BP,相对海平面介于-1.3~-0.4 m。8000~5000 cal BP时,相对海面上升约15.0 m,上升速率达5 m/1 ka。     

Glacial and environmental changes over the last 60 000 years in the Polar Ural Mountains,Arctic Russia,inferred from a high‐resolution lake record and other observations from adjacent areas

Our knowledge about the glaciation history in the Russian Arctic has to a large extent been based on geomorphological mapping supplemented by studies of short stratigraphical sequences found in exposed sections. Here we present new geochronological data from the Polar Ural Mountains along with a high‐resolution sediment record from Bolshoye Shchuchye, the largest and deepest lake in the mountain range. Seismic profiles show that the lake contains a 160‐m‐thick sequence of unconsolidated lacustrine sediments. A well‐dated 24‐m‐long core from the southern end of the lake spans the last 24 cal. ka. From downward extrapolation of sedimentation rates we estimate that sedimentation started about 50–60 ka ago, most likely just after a large glacier had eroded older sediments from the basin. Terrestrial cosmogenic nuclide (TCN) exposure dating (¹⁰Be) of boulders and Optically Stimulated Luminescence (OSL) dating of sediments indicate that this part of the Ural Mountains was last covered by a coherent ice‐field complex during Marine Isotope Stage (MIS) 4. A regrowth of the glaciers took place during a late stage of MIS 3, but the central valleys remained ice free until the present. The presence of small‐ and medium‐sized glaciers during MIS 2 is reflected by a sequence of glacial varves and a high sedimentation rate in the lake basin and likewise from ¹⁰Be dating of glacial boulders. The maximum extent of the mountain glaciers during MIS 2 was attained prior to 24 cal. ka BP. Some small present‐day glaciers, which are now disappearing completely due to climate warming, were only slightly larger during the Last Glacial Maximum (LGM) as compared to AD 1953. A marked decrease in sedimentation rate around 18–17 cal. ka BP indicates that the glaciers then became smaller and probably disappeared altogether around 15–14 cal. ka BP.