从晋北地区地貌演化看桑干河的古流向

第三纪 ,恒山 -小五台山、管涔山和坝缘山地逐渐隆起。源于该山地的桑干河、洋河等河流全部汇入洋河谷地中。第四纪 ,大同 -阳原等盆地形成 ,逐渐吸引桑干河等河流向东流入该盆地。洋河仍循原河道。始成现在的水系格局。     

从晋北地区地貌演化看桑干河的古流向

第三纪，恒山－小五台山、管涔山和坝缘山地逐渐隆起。源于该山地的桑干河、洋河等河流全部汇入洋河谷地中。第四纪，大同－阳原等盆地形成，逐渐吸引桑干河等河流向东流入该盆地。洋河仍循原河道。始成现在的水系格局。     

松辽水系的变迁

现代松辽水系是在松辽盆地地质构造、古地貌发育的基础上,几经变迁逐渐演变而成的。晚第三纪以来,古松辽水系经历了几次大规模的河湖交替。中新世早期,形成了古嫩江—西辽河向心状水系。中新世晚期,形成了大安—大布苏湖和盘山—田庄台湖。上新世为新生代以来的河湖全盛期,泰康期水文网再度出现向心状内陆水系。早更新世末或中更新世初,松花江和下辽河分别切穿了三姓附近的分水岭和铁法丘陵,古松辽向心状水系逐渐转变为现代状态的外流水系。     

三江并流区地貌与环境演化研究

滇西北三江并流区地理环境演化既受青藏高原隆升的影响,同时又具有自己形成演化的特点,还以纵向岭谷地貌、水系形成演化等影响本区及周边的生态环境.三江并流区经历了古新世中新世地表夷平准平原阶段,中新世末第四纪初的岭盆谷形成发展阶段(高原发育期),更新世晚期以来的现代水系峡谷、纵向岭谷和垂向气候形成等几个时期的发展,形成了现今西南纵向岭谷区的主要组成部分,导致了生态环境的通道阻隔效应,形成了独具特色的自然地理区域.     

喀喇昆仑山北坡山地的第四纪构造运动

第四纪构造运动对喀喇昆仑山北坡山地第四纪地质环境的形成和发展起到了极为重要的作用。中生代晚期的燕山运动使本区褶皱回返，进入大陆发展阶段，而形成一系列北西西向构造，奠定了本区地貌发育基本格局。第四纪期间，本区的主干断裂－康西瓦断裂再度复活，中－新生代地层褶皱，错断，沿断裂裂隙喷发的火山岩，穿透了河漫难阶地。山体剧裂的差异抬升，致使本区东西、西两部地貌形态变异很大。主干河流沿断裂活动强烈下蚀，呈直线性伸展，与沿主河新生的次一级张性断裂构成梳状水系。反映山地间歇性上升特点的河谷阶地，在两岸的阶地级数，分布高度上很不一致，显示了构造运动的差异性。     

塔克拉玛干沙漠的形成时代及发展过程

对塔克拉玛干沙漠腹地的近期研究表明，塔里木盆地虽早在白垩纪晚期已出现明显的干旱环境，但具有现代干旱特征的环境始于第三纪末，形成于第四纪初。盆地内部沙漠环境形成中更新世或其晚期。沙漠在晚更新世晚期和全新世中晚期大模型向西、西南地区和东部发展。     

新疆主要尾闾湖演变的构造环境

亚洲中部大地构造格局及地貌轮廓均以山盆体系为特征，所有封闭性盆地中都发育有尾闾湖。晚第三纪以来印度大陆与欧亚大陆强烈碰撞和右旋挤压，将板内构造激活并以冲断、走滑方式将早第三纪晚期准平原化的大部分山地和相关地段再次抬升，形成了现代亚洲中部的山盆体系，同时导致了湖盆的形成演化和湖泊的变迁。湖盆演化包括湖盆联合、分解、迁移和变形等。湖泊不仅随湖盆的构造演化而变迁，而且构造对水系的调控也直接影响湖泊的物理、化学、水文和生态特性。亚洲中部尾闾湖在新构造作用下的演变具有区域同步性和地域差异性。许多尾闾湖，如艾丁湖、艾比湖、玛纳斯湖等都明显受活动构造的影响。     

渭河三阳川盆地最高级阶地的年代厘定及其对河谷发育的指示意义

青藏高原东缘水系的演化历史长期存在着重大争议,鉴于任一水系的形成演化都是通过主要河谷的发育及其不断延展与整合完成的,因此确定河谷发育的起始时代是研究水系演化的关键。本文针对渭河上游三阳川盆地最高级阶地形成时代的研究,发现李家小湾河流阶地砾石层的ESR年代为1.26±0.15 Ma和1.32±0.19 Ma,26Al/10Be埋藏年代为1.45±0.70 Ma和1.04±0.43 Ma,说明该段河谷形成于早更新世晚期。综合青藏高原东缘夷平面、剥蚀面与河流阶地的研究成果,推断该区现代河谷系列主要形成于1.2 Ma以后,河流平均下切速率较高,为0.1~0.32 m/ka,指示了中更新世以来该区快速的地表抬升与河谷发育过程;而其前少数地段的先成河谷下切速率介于0.04~0.29 m/ka之间,说明区域地势总体低平,地表过程以剥蚀夷平为主,即高原东缘的现今水系格局主要是第四纪期间构造和气候共同作用下河流侵蚀的产物。     

淮河形成时代探析

淮河作为中国7大江河之一,有关其形成时代的研究相对匮乏且存在较大的争议。论文通过梳理淮河流域内已有的研究工作,综合层状地貌面和沉积地层记录探讨了淮河不同河段的形成时代。新生代期间,淮河流域内的水系曾经历2次较大的调整,分别发生在古近纪末和上新世末。古近纪和新近纪期间,淮河流域曾广泛发育湖泊沉积,以河湖相沉积环境为主。而第四纪期间,流域内古地理环境逐渐过渡为以河流相沉积环境为主。现代淮河河湖体系的形成发生在早至中更新世,其后经历不断的演变至今。构造活动和气候变化是驱动淮河流域水系演变的主因。上新世末至早更新世初的青藏运动导致了淮河流域内新近纪水文体系的解体,而晚新生代以来气候的转冷可能是湖泊萎缩、河流作用增强的诱因。     

冰臼与壶穴之争述评

一些地质学家在粤东揭西和丰顺所发现的U形谷、冰碛物和石海等第四纪冰川遗迹的证据不足，该区成群出现的“冰臼”，实际上是河床基岩为河流侵蚀所形成的壶穴。控制壶穴形成的构造、岩性、地貌和河流作用等条件，文中作了较为充分的论述。粤西北封开一怀集地区已发现一系列第四纪冰川遗迹，因此广东的第四纪冰川问题，今后仍值得进一步研究。     

Numerical modelling of Quaternary terrace staircase formation in the Ebro foreland basin,southern Pyrenees,NE Iberia

The southern foreland basin of the Pyrenees (Ebro basin) is an exorheic drainage basin since Late Miocene times. Remnants of an early exorheic Ebro drainage system are not preserved, but morphology provides evidence for the Pliocene–Quaternary drainage development. The incision history of the Ebro system is denoted by (i) extensive, low gradient pedimentation surfaces which are associated with the denudation of the southern Pyrenean piedmont around the Pliocene–Quaternary transition and (ii) deeply entrenched Quaternary river valleys. Presumably since the Middle Pleistocene fluvial incision intensified involving the formation of extensive terrace staircase in the Ebro basin. Terrace exposure dating in major Ebro tributary rivers indicates climate‐triggered terrace formation in response to glacial–interglacial climate and glacier fluctuations in the Pyrenean headwaters. The overall (semi)parallel longitudinal terrace profiles argue for progressive base level lowering for the whole Ebro drainage network. The landscape evolution model, TISC, is used to evaluate climatic, tectonic and base level scenarios for terrace staircase formation in the Ebro drainage system. Model simulations are compared with morpho‐climatic, tectonic and chronologic data. Results show that climatic fluctuations cause terrace formation, but the incision magnitudes and convergent terrace profiles predicted by this climate model scenario are not consistent with the (semi)parallel terraces in the Ebro basin. A model including previous (late Pliocene) uplift of the lower Ebro basin results in rapid base‐level lowering and erosion along the drainage network, small late stage incision magnitudes and terrace convergence, which are not in agreement with observations. Instead, continuous Quaternary uplift of both the Pyrenees and the Ebro foreland basin triggers (semi)parallel terrace staircase formation in southern Pyrenean tributary rivers in consistency with the observed longitudinal terrace profiles and Middle–Late Pleistocene incision magnitudes. Forward model simulations indicate that the present Ebro drainage system is actively incising, providing further evidence for uplift.     

青藏高原东南部地貌边界与金沙江水系发育

4000米山顶面高程等值线,可定为高原东南部与外围地区间的地貌界线。低于山顶面的高原面的形成与上新世一早更新世古谷地、盆地的加积相关。元谋运动以来,地貌边界带的发展与高原整体的隆升同步,1500米大河河床高程等值线环绕高原分布,现代水系相继发育。金沙江与长江贯通后东流入海,这是中国大陆地势最终转变为西高东低的标志。     

粤西河流阶地的分布与特征

依据广东西部超过18条河流、39处河流阶地、至少35个14C、热释光的冲积层测龄数据等情况,可知粤西最多有4级河流阶地(不包括湛江组和北海组阶地);多数河流最高阶地靠近现代主河床分布,深切曲流中有河流阶地,反映近数十万年来河床改道不大;西江在封开有广东高度最高(76 m)的河流阶地,而广东高度最高的地下河阶地是111 m,大致显示出地面与地下剥蚀强度的差异;通常山区河流长度越大,河漫滩和河流阶地的高度越大,河流阶地的级数和级别也常增加;在河流上游的下段和中游的上段,河流阶地的高度最大且级数也最多;在晚更新世之前与后,河谷中下游地区的新构造运动趋势由上升变为稳定或沉降;连滩盆地是广东全新世构造沉降最典型的山间盆地。     

罗布泊东阿奇克谷地雅丹地貌与库姆塔格沙漠形成的关系

阿奇克谷地位于罗布泊洼地之东, 93°E以西, 东西长约150km, 南北宽20~30km。为新生代北山与阿尔金山之间的地堑凹地的一部分, 与东面河西走廊的地堑凹地相通。根据出露的雅丹地层河湖相沉积样品所作的ESR测年(2272~10094kaBP)和本区的地质地貌特征可将阿奇克谷地演化与库姆塔格沙漠的发育史归纳为4个时期。①早更新世至中更新世罗布泊古湖扩大时期, 东部湖湾宽约50~60km, 向东延伸至93°15′E或更东; ②中更新世晚期山地上升与古湖湾退缩消失时期, 距今30万年前左右, 青藏高原强烈隆升, 阻挡了海洋水汽的进入, 亚洲内陆加速变干, 由于阿尔金山的左旋向东滑动, 在北面古湖区地层发生了与阿尔山斜交的羽毛状断裂谷群, 并因东北向的断裂上升与东西向的河西地堑谷地斜交, 阻断了疏勒河水不再向西流入罗布泊, 使东部湖湾向西退缩并逐步消失; ③中更新世晚期至晚更新世初, 暴雨径流与强烈的风蚀作用时期, 阿奇克谷地北部的洪积湖相沉积台地支沟口形成雅丹土丘群, 谷地南面库姆塔格沙漠北面羽毛状断裂谷群形成雅丹垄脊和风蚀谷, 谷地中央呈现出季节性的盐碱沼泽和零星雅丹土丘; ④晚更新世末至全新世库姆塔格沙漠扩大, 向北埋没了羽毛状断裂谷(风蚀谷)和雅丹垄脊, 形成了世界上独特的羽毛状沙丘。     

The role of neotectonics and glaciation on terrace formation along the Nysa K odzka River in the Sudeten Mountains (southwestern Poland)

The Nysa K odzka river drainage basin in the Sudeten Mts., SW Poland, preserves a complex late Cainozoic succession that includes eight fluvial series or terraces and deposits from two glacial episodes as well as local volcanic rocks, slope deposits and loess. Fluvial sedimentation took place during the Late Pliocene and from the early Middle Pleistocene (Cromerian), with a long erosion phase (gap) during the Early Pleistocene. Fluvial series are dated to the Late Pliocene, Cromerian, Holsteinian, late Saalian/Eemian, Weichselian, and the Holocene. Glacial deposits represent the early Elsterian and early Saalian stages. Almost all these stratigraphic units have been observed in all geomorphic zones of the river: the mountainous K odzko Basin, the Bardo Mts. (Bardo gorge) and in the mountain foreland. The main phase of tectonic uplift and strong erosion was during the Early Pleistocene. Minor uplift is documented also during the post-early Saalian and probably the post-Elsterian. The post-early Saalian and post-Elstrian uplift phases are probably due to glacio-isostatic rebound. The Quaternary terrace sequence was formed due to base-level changes, epigenetic erosion after glaciations and neotectonic movements. The Cromerian fluvial deposits/terraces do not indicate tectonic influence at all. All other Quaternary terraces indicate clear divergence, and the post-early Saalian terraces also show fault scarps. The fluvial pattern remained stable, once formed during the Pliocene, with only minor changes along the uplifted block along the Bardo gorge, inferring an antecedent origin for the Bardo gorge. Only during the post-glacial times, have epigenetic incisions slightly modified the valley.     

全新世以来山东半岛东北部海面变化的河流地貌响应

对全新世以来山东半岛东北部沿岸的相对海面（基准面）变化,不同河流有截然不同的地貌响应方式。大沽夹河型河流的下游河谷中有分别与相对海面升降对应的溯源堆积期和溯源侵蚀期,但不同规模的河流仍有差异。黄水河型河流河谷未因基准面升降而发生侵蚀或堆积,河谷仅起了输沙通道的作用。此外,大沽夹河型河流的中下游河型在相对海面上升或下降时,还可能发生相应地网状化或曲流化。     

滇西北老君山地区岩浆活动与 长江第一弯形成的关系

在野外观察的基础上，对长江第一弯的形成提出了新认识，首次研究了始新世岩浆活动与长江第一弯形成的关系。提出长江第一弯为始新世滇西北老君山地区（金沙江古河道）强烈的岩浆活动阻塞了古金沙江，导致其上游形成堰塞湖，并在玉龙雪山和哈巴雪山之间决口，在高原隆升的同时河道快速下切，形成虎跳峡，是河水改道东流的结果；计算了处于青藏高原东端研究区的隆升的幅度，对玉龙雪山而言，始新世至更新世，隆升幅度为3300m，加上更新世以来的隆升高度700m，累计隆升高度为4000m左右。     

澧阳平原晚更新世晚期至全新世早中期环境演变及其对人类活动的影响

通过对澧阳平原野外调查,多剖面地层对比分析及岩板垱（YBD）剖面样品的粒度、地球化学元素分析和年代测定,揭示该区晚更新世晚期至全新世早中期环境演变,并探讨其对人类活动的影响。研究结果表明,30~6 ka B.P.间,澧阳平原由冲沟发育的黄土台地向河湖发育的平原丘岗地貌过渡;气候环境经历了弱暖湿-气候变差-凉湿-波动回暖-暖湿的变化;更新世末至全新世早期稻作农业的出现与该区的环境条件和文化基础密切相关;环境演变也推动了古人类活动范围和聚落特征的变化。     

A new conception on the formation of the first bend of Yangtze River: its relations with Eocene magmatic activities

Based on field observations, the author proposes a new understanding on the formation of the first bend of the Yangtze River. The relationship between the formation of the first bend of the Yangtze River and Eocene magmatic activity is expounded, suggesting that the first bend of the Yangtze River is the result from choking of the strong magmatic activity in Eocene. As a result, the upstream became a natural reservoir, whose riverside between Mt. Yulong and Mt. Haba was burst, guiding Jinshajiang River running eastward. At the same time, the drastic uplift of the Qinghai-Tibet Plateau led to the deep dissection of the river cut down the channel, resulting in the formation of the Tiger Leaping Gorge. The magnitude of uplift in the study area (located in the eastern of the Tibetan Plateau) is calculated. Taking Mt. Yulong as a base, the magnitude of lift is 3,300 m from Eocene to Pliocene, adding 700 m since Pleistocene, totaling up to 4,000 m or so.     

A new conception on the formation of the first bend of Yangtze River: its relations with Eocene magmatic activities

Based on field observations, the author proposes a new understanding on the formation of the first bend of the Yangtze River. The relationship between the formation of the first bend of the Yangtze River and Eocene magmatic activity is expounded, suggesting that the first bend of the Yangtze River is the result from choking of the strong magmatic activity in Eocene. As a result, the upstream became a natural reservoir, whose riverside between Mt. Yulong and Mt. Haba was burst, guiding Jinshajiang River running eastward. At the same time, the drastic uplift of the Qinghai-Tibet Plateau led to the deep dissection of the river cut down the channel, resulting in the formation of the Tiger Leaping Gorge. The magnitude of uplift in the study area (located in the eastern of the Tibetan Plateau) is calculated. Taking Mt. Yulong as a base, the magnitude of lift is 3,300 m from Eocene to Pliocene, adding 700 m since Pleistocene, totaling up to 4,000 m or so.