冲积扇形态与沉积特征及其动力学控制因素：进展与展望

武登云; 任治坤; 吕红华; 刘金瑞; 哈广浩; 张弛; 朱孟浩

doi:10.11867/j.issn.1001-8166.2020.038

地球科学进展 >

2020 , Vol. 35 >Issue 4: 389 - 403

DOI: https://doi.org/10.11867/j.issn.1001-8166.2020.038

构造地貌学专栏

冲积扇形态与沉积特征及其动力学控制因素：进展与展望

武登云 ,
任治坤 ,
吕红华 ,
刘金瑞 ,
哈广浩 ,
张弛 ,
朱孟浩

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^1.中国地震局地质研究所活动构造与火山实验室，北京 100029
^2.华东师范大学地理科学学院，上海 200241

武登云（1994-），男，安徽定远人，博士研究生，主要从事构造地貌与活动构造研究. E-mail：wdyecnu@163.com

收稿日期: 2020-01-28

修回日期: 2020-03-13

网络出版日期: 2020-05-08

基金资助

中国地震局地质研究所中央级公益性科研院所基本科研业务专项“青藏高原东北缘鄂拉山与日月山断裂的构造意义”(IGCEA1803);第二次青藏高原综合科学考察研究专题“碰撞以来古地理格局与构造地貌过程”(2019QZKK0704)

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Morphology and Dynamics of Alluvial Fan and Its Research Prospects

Dengyun Wu ,
Zhikun Ren ,
Lü Honghua ,
Jinrui Liu ,
Guanghao Ha ,
Chi Zhang ,
Menghao Zhu

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^1.Key Laboratory of Active Tectonics and Volcanos, Institute of Geology, China Earthquake Administration, Beijing 100029, China
^2.School of Geographic Sciences, East China Normal University, Shanghai 200241, China

Wu Dengyun (1994-), male, Dingyuan County, Anhui Province, Ph.D student. Research areas include tectonic geomorphology and active tectonics. E-mail: wdyecnu@163.com

Received date: 2020-01-28

Revised date: 2020-03-13

Online published: 2020-05-08

Supported by

the National Nonprofit Fundamental Research Grant of China, Institute of Geology, China, Earthquake Administration “The tectonic implications of the Elashan and Riyueshan faults in NE margin of Tibetan Plateau”(IGCEA1803);The Second Tibetan Plateau Scientific Expedition and Research Program "Palaeogeographic pattern and tectonic geomorphologic process since the collision"(2019QZKK0704)

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摘要

冲积扇作为区域环境演变的敏感记录器，日益受到学界关注。通过文献调研，对冲积扇形态特征和动力学控制因素进行了总结梳理。首先对比分析了不同类型冲积扇的沉积学和地貌学特征。进而分别阐明了上游流域基岩岩性、构造运动和气候变化对冲积扇的形态、规模和沉积层序的影响。最后介绍了有助于冲积扇精细化研究的一系列新技术和新方法的应用以及未来研究的发展方向。主要提出重力流和牵引流沉积过程分别塑造碎屑流型和河控型冲积扇两类，并表明冲积扇是多种因素相互控制下的产物：流域基岩性质影响下游冲积扇规模和沉积物组成；构造活动提供山前沉积空间，影响冲积扇形态特征；气候变化决定着第四纪冲积扇沉积层序发育，特别是引发洪水事件的极端气象事件。进一步指出未来需要采用新的手段深入解读冲积扇所蕴含的环境信息。

关键词： 碎屑流型冲积扇; 河控型冲积扇; 岩性; 构造活动; 气候变化

本文引用格式

武登云 , 任治坤 , 吕红华 , 刘金瑞 , 哈广浩 , 张弛 , 朱孟浩 . 冲积扇形态与沉积特征及其动力学控制因素：进展与展望[J]. 地球科学进展, 2020 , 35(4) : 389 -403 . DOI: 10.11867/j.issn.1001-8166.2020.038

Abstract

Alluvial fans can preserve historical records of sediment transport to middle and lower river systems or piedmont basins, which are considered to be sensitive recorders of climate change and tectonic activity. In this paper, the morphological characteristics, control factors and future development trend of alluvial fan are summarized and described. The main understanding is as follows: $①$ According to the gravity flow and traction flow process, fan can be divided into debris flow alluvial fan and fluvial fan. The former is formed under the action of debris gravity flow deposits, which is related to the occasional flood and burst flow in a short time. The latter is braided tributaries depositions which are gradually shallower and spread radially in the direction of fan toe under the traction water transport. $②$ The erodibility of underlying bedrock can affect the scale of downstream alluvial fan, which depends on the sediment production and store factors in the catchment. The easily eroded bedrock may produce more sediment, making the alluvial fan area larger. In the contrast, the erodibility of rocks in the source area can also affect the slope and hydrological characteristics of the valley so that more sediment is deposited in the upstream basin and the alluvial fan formed in the downstream is smaller. $③$ Tectonic activity is the pre-condition for the development of alluvial fans, which provides a space for alluvial fans depositions. Faulting in the piedmont can change the position and morphology of the ancient alluvial fan, and also cause deformation or distortion of the thick sedimentary sequence to record the regional tectonic activity. The quaternary alluvial fan sequence corresponds well to the climate change during the glacial-interglacial period. However, the influence of the flood events caused by extreme meteorological events on alluvial fan deposition should be focused on. $④$ The application of a series of new techniques and methods will help to carry out deep research on alluvial fan in the future, such as high-resolution observation technique, physical simulation experiment, and precise dating.

Key words： Alluvial fan; Fluvial fan; Bedrock lithology; Tectonic activity; Climate change

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