Abstract
Gully systems develop widely in the Yuanmou Dry-hot Valley. Based on the Scheidegger method and the non-parametric method, this study interpreted 1599 gullies using a DEM with a scale of 1:50,000, and remote sensing images were photographed by QuickBird. The objectives are to explore the regularity that is shown in the distributive direction of the gully system and to understand the factors (including aspect, slope, and the neotectonic stress field) that control the distributive direction of the gully system. The results show that (1) the maximum “dominant” direction of the overall, the third and fourth order, the east, above 1400 m gully are 270°; the “dominant” direction 270° has relative superiority. So 270° is the “dominant” direction of the gully system in the Yuanmou Dry-hot Valleys area. (2) The slope of 38° is the threshold value which separates the overall slope range. When the slope is in the range 0–38°, the slope is the dominant factor; when the slope is in the range 38–59°, aspect is the dominant factor. So, with the increase of slope, 38° is the threshold value, and the dominant topographic influence is changed from slope to aspect. (3) The direction of the compressive stress field, 157.5°, is proven not to conflict with the directions 146.3, 157.5, 169, and 180° that are the principal compressive stresses calculated for the gully system. So the collision and extrusion of plates can form fracture surfaces which provide a favorable condition for the development of drainage and gullies. The distributive direction of the gully system is comprehensively affected by the neotectonic stress field, the terrain, and other factors. Therefore, the study of the distributive direction of the gully system not only enriches the content of morphology on the landform but can also be the basis for the evolutional direction of the gully system that is effectively predicted in the study area, and it provides scientific guidance for industrial and agricultural production layout and the construction of infrastructure.
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References
Ai N (1987) On stress-induced erosion. J Soil Water Conserv 1(1):15–23
Ai N, Gu H (1982) The analysis of valley trends and neotectonic stress field in North China. Journal of Chongqing Jiaotong University 3(3):18–27
Ai N, Liang G, Seheidegger AE (1982) The valley trends and neotectonic stress field of Southeast China. Acta Geograph Sin 37(2):111–122
Ai N, Lu H, Wang M (1986) Approaching to the features of the modern tectonic stress field in Lanzhou Region. Journal of Lanzhou University (Natural Sciences) 22(2):81–86
Ai N, Scheidegger AE (1981) Valley trends in Tibet. Z Geomorph suppl(25): 203–212
Arnold JG, Williams JR, Maidment DR (1995) Continuous-time water and sediment-routing model for large basins. J Hydraul Eng 121(2):171–183
Baruch A, Filin S (2011) Detection of gullies in roughly textured terrain using airborne laser scanning data. ISPRS J Photogramm Remote Sens 66(5):564–578
Bouchnak H, Felfoul MS, Boussema MR, Snane MH (2009) Slope and rainfall effects on the volume of sediment yield by gully erosion in the Souar lithologic formation (Tunisia). Catena 78(2):170–177
Buccolini M, Coco L, Cappadonia C, Rotigliano E (2012) Relationships between a new slope morphometric index and calanchi erosion in northern Sicily, Italy. Geomorphology 149:41–48
Chai Z, Fan J, Liu S (2001) Analysis on development characteristics and process of gully in Yuanmon Basin on lower reaches of Jinsha River. Sci Geogr Sin 21(4):339–343
Chen H, Cai Q (2006) Impact of hillslope vegetation restoration on gully erosion induced sediment yield. Sci China Ser D 49(2):176–192
Chorley RJ (1962) Geomorphology and general systems theory. US Government Printing Office, Washington, DC
Clark CD, Hughes AL, Greenwood SL, Spagnolo M, Ng FS (2009) Size and shape characteristics of drumlins, derived from a large sample, and associated scaling laws. Quat Sci Rev 28(7):677–692
Crouch R (1987) The relationship of gully sidewall shape to sediment production. Soil Res 25(4):531–539
Desmet P, Poesen J, Govers G, Vandaele K (1999) Importance of slope gradient and contributing area for optimal prediction of the initiation and trajectory of ephemeral gullies. Catena 37(3):377–392
Fang H, Ji Z (2006) On the formation of gully in Yuanmou Dry-hot Valleys and technology of vegetation restoration. Chin For Sci Technols 22(2):47–50
Fang H, Wei Y, Liu G (2011) Effects of soil nutrients on planted Leucaena leucocephala forest in the dry-hot Jinshajiang river valley. Arid Zone Res 28(2):229–234
Fang S, Liu Z, Huang X, Guo W, Liu Z (2008) Uplift and topography evolution research at FT in Cenozoic of south-eastern slope of Daxing’anling Mountains. J Jilin Univ (Earth Sci Ed) 38(5):771–794
Fuhong H, Li Y, Li L, Zhang Q, Bai L (2005) Assessing gully development in Upper Yangtze River basin based on GPS and GIS. J Soil Water Conserv 19(6):19–22
Gábris G, Kertész Á, Zámbó L (2003) Land use change and gully formation over the last 200 years in a hilly catchment. Catena 50(2):151–164
Gerber EK, Scheidegger AE (1973) Erosional and stress-induced features on steep slopes. Z. Geomorph suppl:38–49.
Grissinger, E. (1996a). “Rill and gullies erosion.” Soil erosion, conservation, and rehabilitation. Marcel Dekker, New York: 153–167.
Grissinger EH (1996b) Reclamation of gullies and channel erosion, Soil erosion, conservation, and rehabilitation. Marcel Dekker, New York, pp 301–313
Kheir RB, Wilson J, Deng Y (2007) Use of terrain variables for mapping gully erosion susceptibility in Lebanon. Earth Surf Process Landf 32(12):1770–1782
Kohibeck F, Scheidegger AE (1977) On the theory of the evaluation of joint orientation measurements. Rock Mech (9):9–25
Kompani-Zare M, Soufi M, Hamzehzarghani H, Dehghani M (2011) The effect of some watershed, soil characteristics and morphometric factors on the relationship between the gully volume and length in Fars Province, Iran. Catena 86(3):150–159
Lu H, Yang S, Ai N (1984) On the connection between the landslide at Sale Mountain and the neotectonic stress field. Journal of Lanzhou University (Natural Sciences) 20(4):96–104
Meng Q-R, Zhang G-W (2000) Geologic framework and tectonic evolution of the Qinling orogen, central China. Tectonophysics 323(3):183–196
Moretti S, Rodolfi G (2000) A typical “calanchi” landscape on the Eastern Apennine margin (Atri, Central Italy): geomorphological features and evolution. Catena 40(2):217–228
Ni Y, An Y, Wang J (1993) Soil and water loss and loess structural joint in Luochuan Yuan. J Soil Water Conserv 7(3):26–31
Nietsch S, Arnold J, Kiniry J, Williams J, King K (2005) Soil and water assessment tool theoretical documentation. Version 2005. Texas Water Resource Institute, College Station
Pan X (1987) The structure in Xikang-Yunnan and the function of rift valley. Chongqing Publishing group
Poesen J, Nachtergaele J, Verstraeten G, Valentin C (2003) Gully erosion and environmental change: importance and research needs. Catena 50(2):91–133
Qian F, Zhou G (1991) Quaternary geology and paleoanthropology of Yuanmou Yunnan. Science Press, Beijing, China
Ries J, Marzolff I (2003) Monitoring of gully erosion in the Central Ebro Basin by large-scale aerial photography taken from a remotely controlled blimp. Catena 50(2):309–328
Rubin DM, Ikeda H (1990) Flume experiments on the alignment of transverse, oblique, and longitudinal dunes in directionally varying flows. Sedimentology 37(4):673–684
Scheidegger A (1964) The tectonic stress and tectonic motion direction in Europe and Western Asia as calculated from earthquake fault plane solutions. Bull Seismol Soc Am 54(5A):1519–1528
Scheidegger A (1979a) On the tectonics of the Western Himalaya. Arch Meteorol Geophys Bioklimatol A 28(1):89–106
Scheidegger AE (1979b) The principle of antagonism in the Earth’s evolution. Tectonophysics 55(3):T7–T10
Singh S (2006) A drainage morphological approach for water resources development of the sur catchment, Vidarbha region. J Indian Soc Remote Sens 34(1):79–88
Souchere V, Cerdan O, Ludwig B, Le Bissonnais Y, Couturier A, Papy F (2003) Modelling ephemeral gully erosion in small cultivated catchments. Catena 50(2):489–505
Stankoviansky M (2003) Gully evolution in the Myjava Hill Land in the second half of the last millennium in the context of the central-European area. Geogr Pol 76(2):89–107
TuZino T, Noda A (2007) Tectonic control over topography and channel sedimentation across the forearc slope of the southern Kurile Trench. Geo-Mar Lett 27(1):1–11
Valentin C, Poesen J, Li Y (2005) Gully erosion: impacts, factors and control. Catena 63(2):132–153
Vandekerckhove L, Poesen J, Oostwoud-Wijdenes D, Nachtergaele J, Kosmas D, Roxo M, Figueiredo TD (2000) Thresholds for gully initiation and sedimentation in Mediterranean Europe.
Wang J (1987) Loessic gully network and neotectonic stress fields. Sci Geogr Sin 7(2):139–147
Wang J, Ni Y, Sun J (1994) A study on structural joints in loess and its practical applications. J Eng Geol 2(4):31–42
Wang L, Wei S, Horton R, Shao MA (2011) Effects of vegetation and slope aspect on water budget in the hill and gully region of the Loess Plateau of China. Catena 87(1):90–100
Werner B (1999) Complexity in natural landform patterns. Science 284(5411):102–104
Wu Y, Cheng H (2005) Monitoring of gully erosion on the Loess Plateau of China using a global positioning system. Catena 63(2):154–166
Xiong D, Yang D, Zhai J, Li J, Su ZA, Dong Y, Shi L (2012) Preliminary study on hydrodynamic characteristics of overland flow and sediment yields of gully heads in Yuanmou Hot-dry Valley. J Soil Water Conserv 26(6):52–62
Yan Q, Zeng S (1985) Geomorphology. Higher Education Press, p 82
Yang D, Xiong D, Zhai J, Su J, Zheng A, Dong Y (2012) Morphological characteristics and causes of gullies in Yuanmou Dry-hot Valley region. Sci Soil Water Conserv 10(1):38–45
Yi W, Yang P (2008) Determination of drainage area threshold for extraction of DEM-based digital drainage network. Jiangxi Hydraulic Science and Technology 34(4):259–262
Yu, F, Liu G, Zhang C (2011) Determination of the main sliding direction of space rock landslide. Mechanic Automation and Control Engineering (MACE), 2011 Second International Conference on, IEEE
Yu Q, Jiang Z, Ai N (1985) A concentrated degree method for calculation of valley trends. Sci Geogr Sin 5(1):1–9
Zhang B, Shi K, Liu C, Ai N, Liu G, Qin F (2009) Changes of seasonal precipitation of Yuanmou Dry-hot Valley in recent 50 years based on method of DFA. Sci Geogr Sin 29(4):561–566
Zhang G, Neng T, Yu Z (1996) Orogenesis and dynamics of Qinling orogen. Science, in China
Zhang X, Chen Y (1997) Study on vegetation rehabilitation on the slopes of the arid and hot valleys in Yuanmou. Yunnan Chin J Appl Environ Biol 3(1):13–18
Zhang X, Yang Z, Zhang J (2003) Lithologic types on hill slopes and revegetation zoning in the Yuanmou hot and dry valley. Sci Silvae Sin 39(4):16–22
Zucca C, Canu A, Della Peruta R (2006) Effects of land use and landscape on spatial distribution and morphological features of gullies in an agropastoral area in Sardinia (Italy). Catena 68(2):87–95
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Financial support for this research was provided by the National Natural Science Foundation of China (Nos. 0.41101348, 40871013, and 41071013).
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Mu, H., Deng, Q., Zhang, B. et al. Distributive directions of gully system in Yuanmou Dry-hot Valley. Arab J Geosci 8, 10313–10324 (2015). https://doi.org/10.1007/s12517-015-1981-6
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DOI: https://doi.org/10.1007/s12517-015-1981-6