共查询到19条相似文献,搜索用时 93 毫秒
1.
在西藏阿里阿伊拉日居山脉南北两麓及切割山脉的各沟谷中,分布着4套早更新世以来的冰川沉积物。根据这些冰川沉积物的地层层序和冰川沉积物的电子自旋共振(ESR)年龄测定结果,将阿伊拉日居山脉南北两麓所发生的4次早更新世以来的冰川作用,分别命名为札达冰期(1161-952 ka BP)、阿伊拉日居冰期(762-730 ka BP)、学朗冰期(336-211 ka BP)和弄穷冰期(105-15 ka BP),并与青藏高原及其他地区冰期进行了对比。各次冰期的冰川性质分别为大型山岳冰川、冰帽、山麓冰川和中小型山谷冰川。全新世时期,现代冰川有过冰川推进。近期冰川则发生了明显的后退。 相似文献
2.
西藏阿伊拉日居山南麓第四纪冰川沉积物及其ESR年龄测定 总被引:7,自引:2,他引:5
在西藏札达盆地北缘阿伊拉日居山南北两麓及切割山脉的各沟谷中, 分布着 4 套第四纪冰川与冰水沉积物, 其冰川沉积物的电子自旋共振(ESR)测年结果分别为 1 161~730 ka BP、319~336 kaBP、211 ka BP和105~15 ka BP. 测年结果表明, 在札达盆地北缘阿伊拉日居山南麓所发生的 4 次冰川作用, 其形成时期分别为早更新世晚期、中更新世中晚期、中更新世晚期和末次冰期. 相似文献
3.
玉龙山西麓更新世冰川作用及其与金沙江河谷发育的关系 总被引:18,自引:5,他引:18
在玉龙山东麓更新世冰川作用研究的基础上,对其西麓和金沙江河谷中的古冰川与冰水沉积物的分布和特征进行了调查.结合ESR测年,划分出4次冰期,即0.7~0.6MaB.P.的玉龙冰期,0.53~0.45MaB.P.的干海子冰期,0.31~0.13MaB.P.的丽江冰期和晚更新世中晚期的大理冰期,其中玉龙冰期为规模较大的山麓冰川,丽江和大理冰期为山谷冰川,干海子冰期则为山麓冰川与山谷冰川的过渡类型.来自玉龙山西坡的玉龙冰期冰碛物充填于现今金沙江谷底的事实和大具金沙江下渡口西岸早更新世金沙江砾石层的发现表明,金沙江在早更新世早期即已存在,也说明了在该段金沙江河谷中多处发现的湖相沉积物是冰川沉积堰塞河谷而成石鼓古湖的结果.在该段金沙江河谷中仅发现拔河50m左右以内的4级河流阶地,且往往以这些湖相沉积为基座的现象,则是石鼓古湖被外泄后金沙江现代河谷形成的结果. 相似文献
4.
念青唐古拉山东南麓更新世冰川沉积物年龄测定 总被引:14,自引:6,他引:14
在念青唐古拉山南北两麓及切割山脉的各沟谷中 ,分布着 3套更新世冰川与冰水沉积物 ,其冰水沉积物的电子自旋共振 (ESR)和光释光 (OSL)测年结果分别为 ( 5 93± 2 6 0 )kaBP与 ( 6 78± 30 7)kaBP ,( 2 0 5± 5 4 )kaBP和 ( 2 5 4± 8 7)kaBP .测年结果表明 ,在念青唐古拉山东南麓所发生的 3次冰川作用 ,分别相当于青藏高原南部的聂聂雄拉冰期、古乡冰期和白玉冰期 相似文献
5.
贡嘎山第四纪冰川遗迹及冰期划分 总被引:22,自引:1,他引:22
在对贡嘎山现代冰川和古冰川考察研究的基础上,结合定位观测分析,对该区第四纪冰川遗迹进行了深入讨论,划分出三次冰期,即中更新世早期的倒数第三次冰期,中更新世晚期的倒数第二次冰期和晚更新世的末次冰期,以及全新世的新冰期和小冰期。提出在早更新世时,由于山体未达到当时冰川发育的雪线高度,所以未发育冰川;中更新世早期的冰期冰川为半覆盖式冰川类型,规模不大;中更新世晚期的冰期冰川是本区最大冰川作用时期,形成网状山麓冰川,东坡冰川曾达磨西台地;晚更新世冰期冰川以山谷冰川为主,以后规模逐次缩小。 相似文献
6.
念青唐古拉山中段第四纪冰期划分 总被引:11,自引:3,他引:11
念青唐古拉山脉呈NE和近EW走向,其主脊海拔6000-7000余米,第四纪冰川活动强烈。根据第四纪地层剖面,地层层序,地质地貌特征及其相互接触关系,在念青唐古拉山中段可清晰地划分出3期冰期,从新到老依次为:拉曲冰期Q3,爬然冰期Q2-3,宁中冰期Q2-1。每次冰期及间冰期沉积物中的砾石及其岩性,砾态,沉积厚度,风化程度等都有明显区别。另外,还对老冰期与冰碛层,各次间冰期和本区冰期与其他地区冰期对比等问题进行了讨论。 相似文献
7.
北京市平原区下伏的泥砂砾石层发现较早,但对其成因一直存在着争议。本文通过对最新钻探资料的分析,经系统的古地磁样品测试,发现泥砂砾石层最早形成于上新世,距今约三百万年,这一时期的砾石层分布最广,厚度很大。此后更新世、全新世也有砾石层形成,但分布范围和厚度都显著减小。资料表明,上新世北京地区气候比较温暖湿润,不存在形成冰川沉积物的条件,此外第四纪的泥砾石层的分布和层位也与第四纪冰期的划分不能对应。北京市平原区下伏泥砂砾石层具有泥石流成因的基本特点,综合各种资料分析,应主要是洪水泥石流成因。 相似文献
8.
从冰川剥蚀作用看念青唐古拉山脉(中段)的隆升 总被引:3,自引:2,他引:1
通过对念青唐古拉山主峰地区第四纪冰碛地层划分与同位素测年,发现主峰地区的第四纪冰川分别形成于700~600kaBP、200~140kaBP和70~30kaBP三个时段,指示了自中更新世以来念青唐古拉山中段开始大规模隆升,冰川活动加剧,并堆积了相应的冰碛物。根据念青唐古拉山主峰地区基岩地层与岩性的空间分布、不同火成岩和变质岩组合的形成深度和不同冰期冰碛物砾石成分统计研究,发现冰川对基岩剥蚀与念青唐古拉山中段隆升过程有着明显的对应关系。本文从念青唐古拉山主峰地区的基岩地层的岩石成分和分布的研究,及其对山脉隆升与冰碛物成分的关系等方面,分析了念青唐古拉山脉的切割及其对山脉隆升的反映。念青唐古拉山主峰地区的隆升过程可较好地与青藏高原的隆起相对比,它应是青藏高原隆升的响应。 相似文献
9.
玉龙山东麓更新世冰川作用 总被引:34,自引:7,他引:27
利用1:10000地形图和航空照片,对玉龙山东麓更新世冰川作用遗迹进行了调查和填图。据冰川与冰水沉积物的钙质胶结物和冰湖相钙板的ESR测年结果,初步划分4次冰期,即0.7 ̄0.6Ma BP的玉龙冰期。其中最早一次冰期为规模较大的山麓冰川,后2次冰期为规模较大的山谷冰川。 相似文献
10.
唐古拉山地区第四纪冰川作用与冰川特征 总被引:4,自引:2,他引:2
自中更新世以来,唐古拉山地区发生过3次更新世冰川作用(即昆仑冰期、倒数第二次冰期和末次错冰期)和2次全新世晚期冰进(即新冰期和小冰期冰进).昆仑冰期(最大冰期)发生在中更新世早期(0.80~0.60MaBP),不仅是本区最早的一次冰期,而且也是冰川规模最大的一次冰期,当时的冰川规模比现代冰川大16~18倍;倒数第二次冰期发生在中更新世晚期(0.30~0.135MaBP),比现代冰川大13~15倍;末次冰期发生在晚更新世晚期,应分为末次冰期早冰阶(75.0~58.0kaBP)和晚冰阶(32.0~15.0kaBP,23.0kaBP时达到极盛),但在唐古拉山地区截止目前还未找到早冰阶的冰川遗迹,因此,只对末次冰期的晚冰阶(LMG)进行了探讨.LMG时,冰川规模比现代冰川大10倍;新冰期发生在全新世高温期后,冰碛物的14C测年为(3540±160)aBP,冰川规模略大于现代冰川;小冰期发生在15~1世纪,冰川规模已接近于现代冰川.由于青藏高原的上升,对高原腹部地区引起的干旱化过程和水分严重不足,使唐古拉山地区的冰川自昆仑冰期以来,冰川规模一次比一次明显的减小. 相似文献
11.
12.
天山末次冰期以来干旱化过程的冰川证据 总被引:3,自引:3,他引:0
依据天山7个有确切年代学资料的典型地区进行冰川面积和平衡线高度等重建,揭示天山地区末次冰期以来冰川经历的扩张和收缩过程。冰川规模在MIS 4~MIS 3大幅度扩张,形成大规模的复合型山谷冰川和山麓冰川;MIS 2冰川扩张显著,但远不及MIS 4~MIS 3,许多山区形成大型山谷冰川;全新世新冰期NG和小冰期LIA都略有扩张,冰碛垄分布在现代冰川外围,冰川类型与现在一致。冰川平衡线高度的降幅亦表现为MIS 4~MIS 3最大,MIS 2以后降幅递减。MIS 4~MIS 3天山冰川大规模扩张与欧亚冰盖演化,巨大冰前湖泊、广阔的湿地的形成为西风提供更多水气带到天山有关;MIS 2至今,随着欧亚冰盖减小到消失,西风带来的水气渐少,干冷的蒙古高压逐渐加强,制约了冰川规模扩张。 相似文献
13.
希夏邦马峰东南富曲河谷的冰川沉积和冰川构造 总被引:2,自引:0,他引:2
在希夏邦马峰(海拔8012m)东南富曲河谷,中更新世以来有三次冰期;即聂拉木、富曲和普罗冰期。它们均可再分为两个亚阶段。聂拉木南的高冰碛平台长3.5m,宽1.5km,厚200m。属于中更新世聂拉木冰期(聂聂雄拉冰期)的巨大山谷冰川沉积,中尼公路从高冰碛平台尾端通过,形成数公里长的冰碛剖面,呈现出美丽多姿的冰川成因类型沉积和冰川构造现象,包括冰下,冰上融出碛,冰内.冰下河道沉积,冰湖沉积,坠碛,流磺等。冰川运动时造成的冰川构造,如断层、滑动面-…等也很清楚,代表了海洋型(暖冰川)冰川沉积和冰川构造特征,是中国目前研究冰川构造最理想的场所。 相似文献
14.
Benxing Zheng 《GeoJournal》1988,17(4):525-543
The uplift of the Himalaya and Qinghai-Xizang plateau began at the end of Pliocene to the beginning of Early Pleistocene, changing the atmospheric circulation in Asia, enhancing the South Asian monsoon and enormously effecting the climatic conditions and glacial development.According to the evidence of glacial deposits, geomorphology, paleobiology, paleopedology, etc., at least four glaciations can be recognized. The uplift of the Himalayas was earlier than that of other mountains, so that the glaciation occurred in Early Pleistocene, forming small piedmont glaciers on the N slope, whilst at the same time there were wide short valley glaciers on the S slope. During the Middle Pleistocene, the height of Himalaya was about 4000 m a s l, the monsoon was strong, and much water vapour reached the interior of the plateau, the most favourable period for glacial development. Great piedmont glaciers and small ice caps formed on the mountains N of Himalayas and great valley glaciers occurred on the S slope, but no great ice sheet covered the plateau.During the early Late Pleistocene, the Himalayas had risen to over 5000 m asl, forming a barrier against the incursion of the Indian monsoon, so that the precipitation decreased sharply on the plateau N of Himalayas, thus diminishing the extent of the glaciation. But on the high mountains of the S part of Xizang and on several high mountains of the S slope of the Great Himalaya, the precipitation increased and the extent of glaciation reached a maximum. Since Last Glaciation, the precipitation of the alpine zone has decreased more sharply, the climate has become drier and colder, becoming unfavourable for glacial development.During the Holocene, three stages may be distinguished, i.e. the recession in Early Holocene (10,000-8000 BP); the disappearance of most glaciers in the Hypsithermal period in Middle Holocene, (8000-3000 BP); and the neoglacial fluctuations in Late Holocene (3000 BP up to present). The glaciers of the Neoglaciation advanced several hundred meters or even 3–5 km farther than existing glaciers. 相似文献
15.
Daoming Xu 《GeoJournal》1991,25(2-3):233-242
Three kinds of moraines can be found in the Muztagh valley on the N slope of Mount K2, Karakorum: an old calco-cement moraine
lying at the altitude of 5000 m asl, a hilly moraine lying at the altitude of 4200–4800 m asl and a new lateral moraine, lying
on both sides of the present river valley. According to the moraines’ geomorphology, they are referred to the Middle Pleistocene
Glaciation, the Late Pleistocene Glaciation and the Post-Glacial Period respectively.
The lowest level of glacial cirques at 4200–4000 m asl, corresponding to the largest Glaciation, belongs to the Middle Pleistocene
(Riss). The ancient cirques at this altitude in the Shaksgam and Yargand valleys are poorly preserved while at the piedmont
of the West Kunlun mountains they are represented in better shape. This means that these ancient cirques had been submerged
and almost removed by the main ice flow of the valleys. Old cirques, however, are well shaped (or reshaped) where associated
with younger cirques at 4600 m als; they could be considered as the product of the Last Glaciation (Würm). Thus, the equilibrium
line altitude (ELA) decreased to 1600 m during the Riss Glaciation and to 1000 m during the Würm Glaciation.
On the basis of the ELA decrease and existence of complex morainic deposits found at the piedmont of the West Kunlun mountains
at about 2200 m asl, the author adheres to the opinion that Riss Glaciation had developed an ice cover (ice sheet), with the
central ice area located in Karakorum and reaching up to the high peaks of the Kunlun mountains, and down to the piedmont
region. During the Last Glaciation an immense ice cap covered the upper parts of the Shaksgam and Yarkant valleys. The paper
also deals with the relations between glaciations and tectonic uplift, indicating that topographic and climatic conditions
were favourable for the large-scale ice development in the Middle and Late Pleistocene. The uplift may have reached 600–800
m during the Postglacial period. The uplift rates are often reflected by the glaciostatic in the Postglacial Age. 相似文献
16.
《Boreas: An International Journal of Quaternary Research》2018,47(2):379-389
This is a synthesis of the glacial history of the northern Urals undertaken using published works and the results of geological surveys as well as recent geochronometric and remote sensing data. The conclusions differ from the classical model that considers the Urals as an important source of glacial ice and partly from the modern reconstructions. The principal supporting evidence for the conventional model – Uralian erratics found on the adjacent plains – is ambiguous because Uralian clasts were also delivered by a thick external ice sheet overriding the mountains during the Middle Pleistocene. Alternative evidence presented in this paper indicates that in the late Quaternary the Ural mountains produced only valley glaciers that partly coalesced in the western piedmont to form large piedmont lobes. The last maximum glaciation occurred in the Early Valdaian time at c. 70–90 ka when glacial ice from the Kara shelf invaded the lowlands and some montane valleys but an icecap over the mountains was not formed. The moraines of the alpine glaciation are preserved only beyond the limits of the Kara ice sheet and therefore cannot be younger than MIS 4. More limited glaciation during MIS 2 generated small alpine moraines around the cirques of the western Urals (Mangerud et al. 2008: Quaternary Science Reviews 27, 1047). The largest moraines of Transuralia were probably produced by the outlet glaciers of a Middle Pleistocene ice sheet that formed on the western plains and discharged across the Polar Urals. The resultant scheme of limited mountain glaciation is possibly also applicable as a model for older glacial cycles. 相似文献
17.
Benjamin J.C. Laabs Kurt A. Refsnider Jeffrey S. Munroe David M. Mickelson Patrick J. Applegate Brad S. Singer Marc W. Caffee 《Quaternary Science Reviews》2009,28(13-14):1171-1187
Recent estimates of the timing of the last glaciation in the southern and western Uinta Mountains of northeastern Utah suggest that the start of ice retreat and the climate-driven regression of pluvial Lake Bonneville both occurred at approximately 16 cal. ka. To further explore the possible climatic relationship of Uinta Mountain glaciers and the lake, and to add to the glacial chronology of the Rocky Mountains, we assembled a range-wide chronology of latest Pleistocene terminal moraines based on seventy-four cosmogenic 10Be surface-exposure ages from seven glacial valleys. New cosmogenic-exposure ages from moraines in three northern and eastern valleys of the Uinta Mountains indicate that glaciers in these parts of the range began retreating at 22–20 ka, whereas previously reported cosmogenic-exposure ages from four southern and western valleys indicate that ice retreat began there between 18 and 16.5 ka. This spatial asynchrony in the start of the last deglaciation was accompanied by a 400-m east-to-west decline in glacier equilibrium-line altitudes across the Uinta Mountains. When considered together, these two lines of evidence support the hypothesis that Lake Bonneville influenced the mass balance of glaciers in southern and western valleys of the range, but had a lesser impact on glaciers located farther east. Regional-scale variability in the timing of latest Pleistocene deglaciation in the Rocky Mountains may also reflect changing precipitation patterns, thereby highlighting the importance of precipitation controls on the mass balance of Pleistocene mountain glaciers. 相似文献
18.
玉龙雪山冰川沉积序列OSL定年 总被引:3,自引:3,他引:0
位于青藏高原东南缘的玉龙雪山分布有欧亚大陆纬度最低的海洋型冰川,其主峰及周边地区保存了大量清晰完整的第四纪冰川遗迹。研究该区第四纪冰川作用遗迹及其冰川作用史,具有重要的理论与实际价值。应用光释光(OSL)测年技术对玉龙雪山冰川沉积物进行了定年,结合前人研究资料,重建玉龙雪山冰川作用史。研究结果表明:玉龙雪山东麓的末次冰期冰碛物主要形成于晚更新世末次冰期最盛时期,其平均年代约在25ka,西麓末次冰期冰碛物形成年代约为50ka,对应于深海氧同位素3阶段中期(MIS3b)。而倒数第二次冰期的年代在240ka左右,处于中更新世晚期,对应于MIS8阶段,当时玉龙雪山存在多条复式山谷冰川。该研究可为玉龙雪山第四纪冰川作用历史的重新认识以及光释光测年技术在该区的应用提供基础资料。 相似文献
19.
0.7Ma以来的念青唐古拉山脉隆升过程——来自冰川剥蚀作用的证据 总被引:1,自引:0,他引:1
通过对念青唐古拉山冰碛地层划分及冰碛物同位素测年,发现最早一期冰碛物形成于0.7~0.6MaBP,指示自中更新世以来念青唐古拉山脉开始隆升,主峰地区发生了大规模的冰川剥蚀作用,形成了大面积分布的冰碛高平台;0.2~0.14MaBP念青唐古拉山又快速隆升,并堆积了刚刚伸出各大沟谷口的高侧碛;0.07~0.03MaBP念青唐古拉山再次小规模隆起,形成各大沟谷内的侧碛和终碛垄;0.01Ma BP还有小规模冰川活动。念青唐古拉山主峰地区的冰川剥蚀作用反映出的山脉隆升过程,可较好地与青藏高原的隆起过程相对比,它应是青藏高原隆升的响应。 相似文献