Cosmogenic ^(10)Be and ^(26)Al Chronology of the Last Glaciation of the Palaeo-Daocheng Ice Cap,Southeastern Qinghai-Tibetan Plateau

The glacial landforms of the Qinghai-Tibetan Plateau （QTP） provide a unique opportunity to research hemispheric and global environmental changes. In this study, we focus on the glacial history of the palaeo-Daocheng Ice Cap （p-DIC） in the southeastern QTP during the last glacial cycle. Based on field investigations, morphostratigraphy, and surface exposure dating of roche moutonnée, polished surface and moraine debris through the terrestrial cosmogenic nuclides （TCN） ^10Be and ^26Al. We identify glacial deposits of the last deglaciation, with minimum ages of 14.9±1.3-18.7±1.7 ka, the Last Glacial Maximum （LGM） of 24.7±2.2 ka, and the early part of the last glacial period （marine oxygen isotope stage （MIS） 3） of 37.1±3.4-45.2±3.9 ka. Our results show that in this region, the extent of the glacial advance during MIS 3 was larger than that during the traditional LGM （MIS 2）. These ages are consistent with prior chronologies, and the ^10Be age is consistent with the ^26Al age for the same sample. Thus, these data provide reliable constraints on climate change in the QTP, during the last glaciation.

Cosmogenic^(10)Be dating of the oldest moraine in the Hengduan Mountains

The Hengduan Mountains is in the transitional zone between the Qinghai-Tibet Plateau(QTP)and the YunnanGuizhou Plateau in China,and a key area for elucidating the Quaternary environmental changes in Asia.The paleo-Daocheng ice cap was located on the Shaluli Hilly Plateau in the northeastern Hengduan Mountains,the oldest moraines in the Hengduan Mountains region were found in the ice cap area.Such glacial landforms provide key evidence to study the timing when this area entered the cryosphere with the uplift of the QTP.However,it is difficult to collect suitable glacial boulders from these moraines for traditional terrestrial in-situ cosmogenic nuclide(TCN)exposure dating because of long-term severe moraine degradation.Here,we collected clast samples from the moraine surface and depth profile to constrain the age of the oldest moraine in Kuzhaori(moraine E)using TCN^(10)Be dating technique.The minimum^(10)Be ages of five clast samples from the moraine surface range from 187.4±1.5 to 576.8±4.3 ka,implying that the moraine has been seriously degraded since deposition.Based on the TCN^(10)Be concentrations of the samples from a depth profile and simulations,the exposure-erosion-inheritance history of the profile was obtained.By fitting to the profile^(10)Be concentrations using the chi-square test,the simulations yielded a reliable age of 626.0±52.5 ka for the moraine.Therefore,the oldest moraine(moraine E)in Kuzhaori was most likely formed at about 0.63Ma ago,corresponding to the marine isotope stage(MIS)16.This glaciation represents the maximum Quaternary glaciation after the QTP was elevated into the cryosphere by the Kunlun-Yellow River Tectonic Movement.

青藏高原地区宇生核素暴露年代数据存在问题探讨

青藏高原是第四纪古冰川研究的理想区域也是宇宙成因核素(terrestrial cosmogenic nuclides,TCN)暴露测年技术应用的天然实验场所。然而,现有的TCN测年数据与先前学者基于其他测年手段的研究结果不一致,显得相对年轻。为了探索其原因,本文尝试对青藏高原1594个TCN测年数据进行统计分析。研究结果表明:1测年样品中97%的样品是漂砾样品,测年数据中约有93%的年代数据小于130 ka;2 280组(n≥3)漂砾样品年代数据中大约76%的漂砾组数据变异系数大于10%,而基岩和羊背石样品组测年数据变异系数较低、相对集中;3冰碛垄表面漂砾样品的不等时暴露与后期侵蚀可能是造成TCN年代数据结果偏年轻的主要原因。本研究可为青藏高原地区冰川地貌TCN暴露年代研究提供重要启示。

祁连山北缘断裂带中段晚第四纪活动速率初步研究

佛洞庙-红崖子断裂属于祁连山北缘断裂带中段逆冲推覆的前锋断裂,也是酒东盆地与祁连山之间的边界逆断裂。断裂运动学速率的准确限定对于理解青藏高原现今构造变形机制及其区域地震危险性至关重要。文中选取该断裂中、西段丰乐河口、石羊圈2个地点,通过地质地貌填图,综合应用地形剖面测量、光释光定年、宇宙成因核素定年和^(14)C定年等手段,获得了约40ka以来的断裂平均垂直滑动速率约为1.1mm/a;考虑到断裂倾角为40°~50°,平均缩短速率为0.9~1.3mm/a。跨酒东盆地的GPS速度剖面给出的酒东盆地10a尺度缩短速率约为1.4mm/a,与地质缩短速率1.0~1.5mm/a几乎一致;酒东盆地内部的隐伏断裂或褶皱变形也可能吸收部分地壳缩短。酒东盆地总体地壳缩短速率约占整个祁连山造山带缩短速率的1/5,高原向NE方向扩展的前锋带现今仍具有强烈的地震活动性。

活动构造研究中相关速率的原地宇宙成因核素年代学约束

活动构造研究中获得的相关速率是解释活动构造运动方式和幅度的重要基础,同时也能够提供检验和建立有关运动学和动力学模型的必要参数。原地宇宙成因核素年代学是近几十年来随着加速质谱的出现而逐渐发展并不断广泛应用于地学,特别是地表过程以及活动构造研究中来的。由于仪器测试费用高以及处理流程比较复杂,国内早期相关研究没有得以广泛开展,然而目前正呈现逐渐升温的趋势。在样品采集以及精细野外地质调查测量的基础上,活动构造研究中的活动断裂运动速率,活动构造区的河流水系侵蚀下切速率以及古地震事件,活动火山喷发事件等均可以通过原地宇宙成因核素年代学定量约束。文中在概述原地宇宙成因核素年代学基本原理的基础上,总结了国内外有关该年代学在活动构造研究应用中的最新成果和资料,重点介绍了基于原地宇宙成因核素年代学方法获取和解释活动构造研究中相关速率的成果。

蒙山国家地质公园拦马墙砾石堆积体暴露测年研究

山东蒙山国家地质公园佛塔谷堆积了大量的巨砾,其形成原因存在着很大的争论。探讨蒙山佛塔谷砾石堆积体的形成年代有助于了解蒙山环境演化和气候变化。关于佛塔谷砾石的微地貌已有相关作者探讨,本文在前人研究的基础上从拦马墙砾石堆积体的宇生核素^(10)Be暴露年代以及全新世以来的气候环境和人类文化等方面进行探讨。研究结果表明:①拦马墙砾石宇生核素^(10)Be暴露年代结果为5.0～6.0 ka BP左右,不支持先前发表的"8.2 ka BP拦马冰期"的结论;②全新世以来山东蒙山区域处于一个暖湿的环境下,尽管有几次降温事件,但是不足以提供形成冰川的条件。

宇宙成因核素埋藏年龄测定及其在地球科学中的应用

原地生成宇宙成因核素埋藏测年方法,在晚新生代沉积物尤其是陆相碎屑沉积物测年上具有广泛的应用前景。在同一岩石或矿物中的宇宙成因核素对,例如26Al和10Be在地表的生成速率比值是固定的,不受纬度和海拔的影响,但是这一核素对分别具有不同的半衰期。在地表经历了暴露的沉积物被埋藏后,该比值会随着时间而降低,因此具有不同的半衰期的核素对(例如26Al/10Be)可以作为一种地质时钟,测年范围在几十万a至5Ma。文中简要介绍了目前常用的4种方法及其应用:暴露-埋藏图解法、深度剖面法、等时线法以及26Al-21Ne和10Be-21Ne法。

冰碛垄表面碎屑物质宇生核素暴露测年可行性研究

原地生宇宙成因核素(宇生核素)^(10)Be和^(26)Al暴露测年技术已广泛应用于各种地貌年代测定,尤其是在冰川地貌年代测定中备受青睐。多数学者通常选择冰碛垄表面散布的冰川漂砾作为测年对象。然而,冰川漂砾在暴露测年研究中存在暴露后期翻转、不等时暴露等问题,不仅影响冰川地貌测年的精度,而且难以获得较老的冰川地貌年代。冰碛垄表面碎屑物质,一直附着于冰碛垄"表面",可以规避冰川漂砾测年存在的不等时暴露问题,而且可以减少测试样本量、降低测试费用。因此,本文尝试探讨利用冰碛垄表面碎屑物质进行暴露测年研究的可行性,可望为较老冰川地貌暴露测年研究提供新的思路。

宇宙成因核素^(10)Be,^(26)Al:原理及其在地表过程中的应用

地表岩石中宇宙成因核素10Be和26Al含量是侵蚀速率和辐射时间的函数,通过对岩石中10Be和26Al含量的测定能反映较长时间(103~107a)和较大空间尺度上的侵蚀作用大小和过程.根据10Be含量估算出长江中下游地区平均侵蚀速率为30~60m·Ma-1,攀枝花至三峡长江流域内地表平均侵蚀速率为200m·Ma-1.

陆地原位宇宙成因核素(TCN)在地表过程与构造活动关系研究中的应用

大地构造、气候变化和地表过程间的耦合作用被视为今后10年内六大地学新课题之一,而从事这一重大课题研究的有效途经便是陆地原位宇宙成因核素的研究和应用。从目前该领域的研究实践来看,经常使用的是3He1、0Be1、4C2、1Ne2、6Al和36Cl核素,其中石英的26Al和10Be的配合使用最为普遍。通过陆地原位宇宙成因核素(TCN)方法基本原理的阐释,并结合当今国际上该领域利用10Be和26Al在暴露年龄与侵蚀速率、沉积物埋藏年龄以及河流下切速率等方面的工作实例,介绍陆地原位宇宙成因核素在地表过程以及地表过程与构造活动相互关系研究上的应用。

^(26)Al/^(10)Be埋藏测年及其在洞穴沉积年代学研究中的应用

长期暴露于地表的石英砂被快速搬入洞穴或埋藏,不再接受宇宙射线辐射,埋藏前所积累的陆地宇生核素26A l和10B e随时间指数衰减。据此用加速器质谱计测定沉积物中石英样品现存的26A l/10B e可计算其埋藏年代。用此方法本文对周口店第一地点的下部地层年代作了初探。此次研究表明自第10层以下的沉积物其年代很可能≥1 M a。

地磁场强度变化对暴露年代测定的影响及校正

在10^3～10^5a的尺度上，地磁场强度变化是影响陆地宇生核素生成速率的主要因素，其影响程度取决于样品的地理位置和暴露时间。根据已有的磁场古强度数据，模拟200ka以来海拔2km、25°N和40°N的地表^19Be生成速率的变化，进而分析地表宇生核素生成速率变化对岩石暴露年代测定的影响及其模式年龄的校正。校正磁场强度变化后，海拔2km、25°N上，50～200ka的模式年龄可被压缩14％～19％，大于1d的误差，相同海拔40°N上的模式年龄可减小约8％。时中低纬两组模式年龄的校正充分证明，磁场强度引起的陆地字生核素生成速率变化是暴露年代测定中主要误差源之一，尤其在低纬高海拔地区这一影响更不容忽视。

古滑坡测年方法与定年精度的提高途径

明确滑坡每次活动准确的年代对于揭示一个地区滑坡在时间上的活动规律,进而评价该地区的滑坡灾害风险至关重要。本文对宇宙成因核素(TCN)、光释光(OSL)和14 C等古滑坡测年方法研究的现状和成果进行了总结,简要介绍了不同的古滑坡测年方法,重点阐释了滑坡体、次生沉积物、滑动面、滑坡塘、滑坡后壁、滑床以及滑坡伴生堰塞湖等不同的地貌部位和测年介质以及选择不同古滑坡测年方法的局限性与使用条件,并根据目前古滑坡测年存在的问题和难点,探讨了提高古滑坡定年精度的途径。

继承性宇生核素对暴露测年结果影响的定量分析方法探讨

宇生核素暴露测年过程中,通常假设在样品最后一次暴露前,样品中的宇生核素(继承性宇生核素)浓度为0。然而,大量的测年数据研究发现,样品的暴露年代结果会受到继承性核素的影响从而高估地貌的真实年代。因此,如何降低继承性核素对暴露年代结果的影响或者定量分析继承性核素的影响程度不仅可为地貌演化提供准确的年代数据,而且对宇生核素暴露测年技术的研究具有重要意义。因此,本文以宇生核素暴露测年技术在冰川地貌中应用为例,通过分析继承性核素的研究概况,并结合宇生核素暴露测年原理,探讨继承性核素对测年结果影响的定量分析方法。研究结果表明:①通过样品中n(26Al)/n(10Be)值[即同一样品中宇生核素Al26与Be10浓度(单位为atom/g)的比值]以及同一地貌位置多个的样品年代数据分布情况可初步判断测年结果是否受到继承性核素的影响;②通过现代冰川冰碛物中宇生核素的浓度可以定量分析继承性核素对暴露测年结果的影响;③通过计算冰碛垄顶部和一定深度(>2~3 m)样品的宇生核素浓度差,可以减少继承性核素的影响。本研究内容对冰川地貌宇生核素暴露测年具有重要意义。

Last Deglaciation Climatic Fluctuation Record by the Palaeo-Daocheng Ice Cap, Southeastern Qinghai-Tibetan Plateau

The last deglaciation, a key period for understanding present and future climate changes, has long been the hot topic for palaeoclimatological study. The Qinghai-Tibetan Plateau（QTP） is often a target study area for understanding hemispheric, or even global environment changes. The glacial landforms on the QTP provide a unique perspective for its climate change. In order to investigate the onset of the last deglaciation at the QTP and its regional correlation, the terrestrial cosmogenic nuclides（TCN） 10 Be and 26 Al surface exposure dating was chosen to date the roche moutonnée, the polished surface and the moraine debris located at the palaeo-Daocheng Ice Cap（pDIC）, southeastern QTP. Our results show that the onset of the last deglaciation is at about 19 ka, followed by another warming event occurring around 15 ka in the p-DIC area. These timings agree well with other records, e.g. equivalent with a rapid sea level rise at 19 ka and the onset of B？lling warming event at about 15 ka. Thus, our new data can provide good reveal constraint on the climate evolution at the QTP.

10Be Exposure Ages Obtained From Quaternary Glacial Landforms on the Tibetan Plateau and in the Surrounding Area

In situ terrestrial cosmogenic nuclide （TCN） exposure dating using 10Be is one of the most successful techniques used to determine the ages of Quaternary deposits and yields data that enable the reconstruction of the Quaternary glacial history of the Tibetan Plateau and the surrounding mountain ranges. Statistical analysis of TCN 10Be exposure ages, helps to reconstruct the history of glacial fluctuations and past climate changes on the Tibetan Plateau, differences in the timing of glacier advances among different regions. However, different versions of the Cosmic-Ray-prOduced NUclide Systematics on Earth （CRONUS-Earth） online calculator, which calculates and corrects the TCN ages of Quaternary glacial landforms, yield different results. For convenience in establishing contrasts among regions, in this paper, we recalculate 1848 10Be exposure ages from the Tibetan Plateau that were published from 1999 to 2017 using version 2.3 of the CRONUS-Earth calculator. We also compare the results obtained for 1594 10Be exposure ages using different versions （2.2, 2.3 and 3.0） of the CRONUS- Earth calculator. The results are as follows. （1） Approximately 97% of the exposure ages are less than 200 ka. A probability density curve of the exposure ages suggests that greater numbers of oscillations emerge during the Holocene, and the peaks correspond to the Little Ice Age, the 8.2 ka and 9.3 ka cold events; the main peak covers the period between 12 and 18 ka. （2） In most areas, the newer versions of the calculator produce older 10Be exposure ages. When different versions of the CRONUS-Earth calculator are used, approximately 29% of the 10Be exposure ages display maximum differences greater than 10 ka, and the maximum age difference for a single sample is 181.1 ka.

10Be exposure ages of Quaternary Glaciers in Antarctica

In situ terrestrial cosmogenic nuclide(TCN)has been widely applied to date the ages of Quaternary glacial deposits in Antarctica and plays an important role in reconstructing the glacial evolution and climate change.It helps to under‐stand the Antarctic ice sheet's evolution process in Quaternary and shed light on the application of Cosmogenic Nu‐clide exposure dating technique in Glacial Geomorphology.In this paper,we retrieved 49510Be age samples in Ant‐arctica from literature published between 2004 and 2020 and recalculated the TCN ages using version 3.0 online cal‐culator of Cosmic-Ray Produced Nuclide Systematics on Earth(CRONUS-Earth).Several conclusions can be drawn from the results:(1)75%of the exposure ages are younger than 400 ka,and 91%younger than 1,100 ka.Northern Antarctic Peninsula exposure result is visibly younger than the main glaciers in East Antarctica due to climate change and geological evaluation since the LGM(Last Glacial Maximum).(2)TCN ages are relevant to the samples'relative positions in the Antarctic continent,but a relationship between their ages and elevations is yet to be determined based on the collected data.