Controlling Factors and Types of Geomorphologic Landscapes in Danxiashan UNESCO Global Geopark of China

doi:10.19657/j.geoscience.1000-8527.2023.099

Abstract

Abstract:

Danxiashan UNESCO Global Geopark is characterized by well-developed Danxia landscape in humid climate of South China, where geomorphologic features and genetic analysis of individual landforms have received much attention in previous studies. However, the controlling factors of landscape development across the Danxia Basin remain poorly understood, and the relationship between fault systems and peaks is yet to be well recognized. In this study, methods such as field survey, rock hardness measurement, remote sensing interpretation of liner structures, and experimental analysis of rock samples were used to illustrate the roles of lithology, depositional facies, and tectonic uplift and dissection in shaping the landscape evolution and to propose a gene-tic and morphologic classification of Danxia landscape. The Upper Cretaceous continental red beds in the Danxia Basin consist of the Changba and Danxia formations. The Changba Formation has a larger outcrop area, forming gentle low hills, while the Danxia Formation is concentrated and characterized by well development of cliffs, representing the typical Danxia landscape. The Danxia Formation is composed of coarse clastic rocks of alluvial fans and eolian sandstones, and is featured by having great thickness, tight cementation, high density and hardness, and being resistant to weathering. In contrast, the Changba Formation consists dominantly of fine-grained muddy clastic rocks deposited in river and lake environments, which are less resistant to weathering and cannot support Danxia landscape with cliffs. The Himalayan tectonic movement likely caused the overall uplift of the Danxia Basin, which resulted in the formation of a series of NE-trending faults and NNE-, NW-, and nearly EW-trending joints. The fracture surfaces may have facilitated subsequent weathering and erosion, producing prominent cliffs, reticulated valleys, and peculiar peaks and rocks. The Danxiashan area is in a subtropical humid climate, where weathering, collapse, water erosion, and karst processes are the main landscape-shaping external forces. Accordingly, the genesis of Danxia landscape is classified into five categories, i.e., collapse-scour, collapse-accumulation, weathering-denudation, river erosion, and dissolution-sedimentation types. The cliff development is a key element of Danxia landscape, and the different combinations of cliff quantities and types formed hills and gorges. Based on these features, the morphological types of Danxia landscape in Danxia-shan are divided into six major categories and twenty-two specific types. This paper has theoretical significance and practical values because it provides a better understanding of the formation processes of Danxia landscape in humid climate, and foundational materials for construction of national park, scientific mountain, and geoscience study travel.

Key words: Danxia landscape, landscape type, red bed lithology, tectonic dissection, weathering

CLC Number:

P931
P542.3

GUO Fusheng, LING Yuanyuan, CHEN Liuqin, ZHOU Wanpeng, LI Hongwei, CHENG Liangkai, WU Zhichun, LI Guangrong, GUO Zhen, LI Bin. Controlling Factors and Types of Geomorphologic Landscapes in Danxiashan UNESCO Global Geopark of China[J]. Geoscience, 2023, 37(06): 1665-1679.

Figures/Tables 19

References 32

[1]	冯景兰, 朱翔声. 广东曲江仁化始兴南雄地质矿产[J]. 两广地质调查所年报, 1928, 第1号: 1-65.
[2]	陈国达, 刘辉泗. 江西贡水流域地质[J]. 江西地质汇刊, 1939, 第6号: 1-64.
[3]	曾昭璇, 黄少敏. 中国东南部红层地貌[J]. 华南师院学报(自然科学版), 1978, 10(1): 56-73.
[4]	ZHU C, PENG H, OUYANG J, et al. Rock resistance and the development of horizontal grooves on Danxia slopes[J]. Geomorphology, 2010, 123(1/2): 84-96. DOI URL
[5]	彭华, 邱卓炜, 潘志新. 丹霞山顺层洞穴风化特征的试验研究[J]. 地理科学, 2014, 34(4): 454-463. DOI
[6]	YAN L B, PENG H, ZHANG S Y, et al. The spatial patterns of red beds and Danxia landforms: Implication for the formation factors-China[J]. Scientific Reports, 2019, 9: 1961. DOI PMID
[7]	朱诚, 马春梅, 张广胜, 等. 中国典型丹霞地貌成因研究[M]. 北京: 科学出版社, 2015.
[8]	章桂芳, 陈凯伦, 张浩然, 等. 基于DEM的丹霞地貌演化阶段划分[J]. 中山大学学报(自然科学版), 2018, 57(2): 12-21.
[9]	陈留勤, 李鹏程, 郭福生, 等. 粤北丹霞盆地晚白垩世丹霞组沉积相及古气候意义[J]. 沉积学报, 2019, 37(1): 17-29.
[10]	陈留勤, 郭福生, 邵崇建, 等. 江西省丹霞地貌特征及其控制因素探讨[J]. 地质学报, 2022, 96(11): 4023-4037.
[11]	陈留勤, 李馨敏, 郭福生, 等. 丹霞山世界地质公园蜂窝状洞穴特征及成因分析[J]. 地质论评, 2018, 64(4): 895-904.
[12]	CHEN L Q, GUO F S, LIU F J, et al. Origin of tafoni in the Late Cretaceous aeolian sandstones, Danxiashan UNESCO Global Geopark, South China[J]. Acta Geologica Sinica, 2019, 93(2): 451-463. DOI URL
[13]	CHEN X, CHEN L Q, ZHANG Y H, et al. Lithological and environmental controls on large tafoni along conglomerate cliffs in subtropic humid Danxiashan UNESCO Global Geopark[J]. Journal of Mountain Science, 2021, 18(5): 1131-1143. DOI
[14]	CHEN L Q, SHI Y X, NG Y, et al. Roles of algae in honeycomb weathering in humid climate:An example from Danxiashan UNESCO Global Geopark of China[J]. Geoheritage, 2022, 14(4): 120. DOI
[15]	史月欣, 陈留勤, 杜丁丁, 等. 丹霞山陡坡上风化洞穴的基本特征及成因探讨[J]. 热带地理, 2023, 43(1): 103-114. DOI
[16]	杨志军, 都衡恒, 罗曦, 等. 广东丹霞山红色岩层中白斑成因的矿物学研究[J]. 矿产与地质, 2022, 36(1): 129-137.
[17]	胡金涛, 杨志军, 何旺, 等. 广东丹霞山白垩系红色砂岩崖壁上风化洞穴成因的矿物学研究[J]. 矿物岩石地球化学通报, 2023, 42(1): 198-205.
[18]	黄进. 丹霞地貌坡面发育的一种基本方式[J]. 热带地理, 1982, 3(2): 107-134.
[19]	黄进. 丹霞山地貌[M]. 北京: 科学出版社, 2010.
[20]	彭华. 中国红石公园——丹霞山[M]. 北京: 地质出版社, 2004.
[21]	郭福生, 姜勇彪, 胡中华, 等. 龙虎山世界地质公园丹霞地貌成景系统特征及其演化[J]. 山地学报, 2011, 29(2): 195-201.
[22]	郭福生, 朱志军, 黄宝华, 等. 江西信江盆地白垩系沉积体系及其与丹霞地貌的关系[J]. 沉积学报, 2013, 31(6): 954-964.
[23]	郭福生, 陈留勤, 严兆彬, 等. 丹霞地貌定义、分类及丹霞作用研究[J]. 地质学报, 2020, 94(2): 361-374.
[24]	郭福生, 何小芊, 闫罗彬. 漫话丹霞[M]. 北京: 科学出版社, 2022.
[25]	彭华. 丹霞地貌学[M]. 北京: 科学出版社, 2020.
[26]	张显球. 丹霞盆地白垩系的划分与对比[J]. 地层学杂志, 1992, 16(2): 81-95.
[27]	张显球, 林小燕. 粤北丹霞盆地白垩系长坝组的介形类动物群[J]. 微体古生物学报, 2013, 30(1): 58-86.
[28]	YOUNG R W, WRAY R A L, YOUNG A R M. Sandstone Landforms[M]. Cambridge: Cambridge University Press, 2009.
[29]	吴起俊. 丹霞盆地的基本地质特征究[J]. 经济地理, 1994(增): 1-21.
[30]	REN J Y, TAMAKI K, LI S T, et al. Late Mesozoic and Ceno-zoic rifting and its dynamic setting in Eastern China and adjacent areas[J]. Tectonophysics, 2002, 344(3/4): 175-205. DOI URL
[31]	WANG Y, WANG Y J, LI S B, et al. Exhumation and landscape evolution in eastern South China since the Cretaceous: New insights from fission-track thermochronology[J]. Journal of Asian Earth Sciences, 2020, 191: 104239. DOI URL
[32]	吴甲添, 刘建雄, 廖示庭. 丹霞盆地地质特征和演化[J]. 中国区域地质, 2001, 20(3): 274-279.

地层	制高点个数	山顶海拔高度(m)		制高点与山脚最大落差(m)
地层	制高点个数	最大值	最小值	制高点与山脚最大落差(m)
丹霞组三段	38	600	190	320
丹霞组二段	152	640	180	440
丹霞组一段	157	570	190	460

地层	制高点个数	山顶海拔高度(m)		制高点与山脚最大落差(m)
地层	制高点个数	最大值	最小值	制高点与山脚最大落差(m)
丹霞组三段	38	600	190	320
丹霞组二段	152	640	180	440
丹霞组一段	157	570	190	460

地层	泥质杂基	胶结物			样品数
地层	泥质杂基	自生黏土	方解石	铁质	样品数
丹霞组三段	5.7	6.0		4.7	3
丹霞组二段	5.4	5.4	10.4	6.0	6
丹霞组一段	8.0	2.0	6.7	6.0	3
长坝组四段	10.0		13.3	3.0	3
长坝组三段	7.6	2.0	10.0	5.4	5
长坝组二段	5.0		40.0	10.0	1
长坝组一段	15.0			8.8	4

地层	泥质杂基	胶结物			样品数
地层	泥质杂基	自生黏土	方解石	铁质	样品数
丹霞组三段	5.7	6.0		4.7	3
丹霞组二段	5.4	5.4	10.4	6.0	6
丹霞组一段	8.0	2.0	6.7	6.0	3
长坝组四段	10.0		13.3	3.0	3
长坝组三段	7.6	2.0	10.0	5.4	5
长坝组二段	5.0		40.0	10.0	1
长坝组一段	15.0			8.8	4

地层	CaO	MgO	样品数
丹霞组三段	3.13	0.66	4
丹霞组二段	7.51	0.66	4
长坝组四段	5.80	1.17	4
长坝组三段	5.26	2.08	4