Quantitative apportionment of slope aspect and altitude to soil moisture and temperature and plant distribution on alpine meadow

doi:10.13287/j.1001-9332.201705.032

Abstract

Abstract: For understanding the effect of aspect and altitude of hill on soil moisture and temperature as well as the vegetation community, we selected an alpine meadow located on a hill in north-eastern Tibet Plateau as our study area. Data on soil moisture and temperature, as well as plant distribution pattern in this mountain ecosystem were collected. We used regression analysis, CCA ordination and variance decomposition, to determine the impacts of the key factors (aspect, altitude, soil temperature and moisture) on plant diversity distribution in 189 sample sites of the hill. The results showed that the plant diversity of shady aspect and bottomland was highest and lowest, respectively. The plant diversity of the shady aspect and on the ridge of the hill increased initially and then decreased with the increasing altitude, but the plant diversity of the sunny aspect increased with the increasing altitude. At 0-30 cm soil layer, the soil temperature of the sunny aspect was higher than that of other aspects, but the soil temperature at 0-20 cm soil layer did not change with the increa-sing altitude. The soil moisture of shady aspect was higher than that of other aspects, and increased with the increasing altitude. The aspect and altitude explained 100% of soil temperature changes and 51.8% of soil moisture variation. Aspect alone explained 72.2% of soil temperature variation and altitude alone explained 51.8% of soil moisture variation, which had the highest contribution rate individually. Most plants were distributed on the shady aspect and on the ridge, and at medium altitude. Sedges mainly grew on the shady aspect, while Gramineae grew on the sunny aspect, the ridge was an ecotone. Cyperaceae, Gramineae and Leguminosae were mainly distributed in low altitude zone. Hill aspect and altitude totally explained 28.6% of plant abundance variation, hill aspect alone explained 19.9% of plant abundance variation. The management of grassland production and ecological restoration in alpine meadow ecosystem should consider the effect of landform on soil and vegetation, and the hill aspect should be priority factor instead of altitude when planning management interventions.

NIU Yu-jie, ZHOU Jian-wei, YANG Si-wei, WANG Gui-zhen, LIU Li, HUA Li-min. Quantitative apportionment of slope aspect and altitude to soil moisture and temperature and plant distribution on alpine meadow[J]. Chinese Journal of Applied Ecology, 2017, 28(5): 1489-1497.

References

[1] Klein JA, Harte J, Zhao XQ. Experimental warming causes large and rapid species loss, dampened by simulated grazing, on the Tibetan Plateau. Ecology Letters, 2004, 7: 1170-1179
[2] Zhu Y (朱烨), Fang X-Q (方秀琴). Correlation analysis of vegetation cover and terrain in Tibetan Plateau. Geospatial Information (地理空间信息), 2015, 13(6): 135-137 (in Chinese)
[3] Tang Z-Y (唐志尧), Fang J-Y (方精云). A review on the elevational patterns of plant species diversity. Biodiversity Science (生物多样性), 2004, 12(1): 20-28 (in Chinese)
[4] Gaston KJ. Global patterns in biodiversity. Nature, 2000, 405: 220-227
[5] Liu Y (刘洋), Zhang J (张健), Yang W-Q (杨万勤). Responses of alpine biodiversity to climate change. Biodiversity Science (生物多样性), 2009, 17(1): 88-96 (in Chinese)
[6] Fang J-Y (方精云), Shen Z-H (沈泽昊), Cui H-T (崔海亭). Ecological characteristics of mountains and research issues of mountain ecology. Biodiversity Science (生物多样性), 2003, 12(1): 10-19 (in Chinese)
[7] Ying LX, Shen ZH, Piao SL, et al. Terrestrial surface-area increment: The effects of topography, DEM resolution, and algorithm. Physical Geography, 2014, 35: 297-312
[8] Cantón Y, Del Barrio G, Solé-Benet A, et al. Topographic controls on the spatial distribution of ground co-ver in the Tabernas badlands of SE Spain. Catena, 2004, 55: 341-365
[9] Burt TP, Butcher DP. Topographic controls of soil moisture distributions. Journal of Soil Science, 1985, 36: 469-486
[10] Huang R-L (黄瑞灵), Zhou H-K (周华坤), Liu Z-H (刘泽华), et al. Effects of slope aspect and altitude on the soil seed bank under different vegetations in Laji Mountains of Qinghai Province, Northwest China. Chinese Journal of Ecology (生态学杂志), 2013, 32(10): 2679-2686 (in Chinese)
[11] Burt TP, Butcher DP. Topographic controls of soil moisture distributions. Journal of Soil Science, 1985, 36: 469-486
[12] Ou Y-D (区余端), Su Z-Y (苏志尧), Li Z-K (李镇魁), et al. Effects of topographic factors on the distribution patterns of ground plants with different growth forms in montane forests in North Guangdong, China. Chinese Journal of Applied Ecology (应用生态学报), 2011, 22(5): 1107-1113 (in Chinese)
[13] Liu X-Y (刘兴元), Long R-J (龙瑞军). Mechanism and scheme of ecological compensation for alpine rangeland in the northern Tibet, China. Acta Ecologica Sinica (生态学报), 2013, 33(11): 3404-3414 (in Chinese)
[14] Zeng X-G (曾贤刚), Tang K-H (唐宽昊), Lu Y-L (卢熠蕾). Fence effect: Property division and integrity of grassland ecosystem. China Population, Resources and Environment (中国人口·资源与环境), 2014, 24(2): 88-93 (in Chinese)
[15] Zhang C-S (张昌顺), Xie G-D (谢高地), Bao W-K (包维楷), et al. Effects of topographic factors on the plant species richness and distribution pattern of alpine meadow in source region of Lancang River, Southwest China. Chinese Journal of Ecology (生态学杂志), 2012, 31(11): 2767-2774 (in Chinese)
[16] Han D-Y (韩大勇), Yang Y-X (杨永兴), Yang Y (杨杨), et al. Species composition and succession of swamp vegetation along grazing gradients in Zoige Pla-teau, China. Acta Ecologica Sinica (生态学报), 2011, 31(20): 5946-5955 (in Chinese)
[17] Dove ADM, Cribb TH. Species accumulation curves and their applications in parasite ecology. Trends in Parasitology, 2006, 22: 568-574
[18] Fang J-Y (方精云). Exploring altitudinal patterns of plant diversity of China’s Mountains. Biodiversity Science (生物多样性), 2004, 12(1): 1-2 (in Chinese)
[19] Liu Z (刘哲), Li Q (李奇), Chen D-D (陈懂懂), et al. Patterns of plant species diversity along an altitudinal gradient and its effect on above-ground biomass in alpine meadows in Qinghai-Tibet Plateau. Biodiversity Science (生物多样性), 2015, 23(4): 451-462 (in Chinese)
[20] Wang Y-G (王应刚), Zhang Q-H (张秋花), Li Y (李赟). Plant species diversity in hilly regions of Fangshan Mountain. Chinese Journal of Ecology (生态学杂志), 2005, 24(12): 1430-1433 (in Chinese)
[21] Fu B-P (傅抱璞). The effects of topography and elevation on precipitation. Acta Geographica Sinica (地理学报), 1992, 47(4): 302-314 (in Chinese)
[22] Xu Y-J (徐远杰), Chen Y-N (陈亚宁), Li W-H (李卫红), et al. Distribution pattern and environmental interpretation of plant species diversity in the mountainous region of Ili River Valley, Xinjiang, China. Chinese Journal of Plant Ecology (植物生态学报), 2010, 34(10): 1142-1154 (in Chinese)
[23] O’Brien EM, Field R, Whittaker RJ. Climatic gradients in woody plant (tree and shrub) diversity: Water-energy dynamics, residual variation and topography. Oikos, 2000, 89: 588-600
[24] Lacoul P, Freedman B. Relationships between aquatic plants and environmental factors along a steep Himala-yan altitudinal gradient. Aquatic Botany, 2006, 84: 3-16
[25] Kamrani A, Jalili A, Naqinezhad A, et al. Relationships between environmental variables and vegetation across mountain wetland sites, N. Iran. Biologia, 2011, 66: 76-87
[26] Han J, Shen ZH, Ying LX, et al. Early post-fire rege-neration of a fire-prone subtropical mixed Yunnan pine forest in Southwest China: Effects of pre-fire vegetation, fire severity and topographic factors. Forest Ecology and Management, 2015, 356: 31-40
[27] Fang J-Y (方精云), Wang X-P (王襄平), Shen Z-H (沈泽昊), et al. Methods and protocols for plant community inventory. Biodiversity Science (生物多样性), 2009, 17(6): 533-548 (in Chinese)
[28] Sun R-H (孙然好), Chen L-D (陈利顶), Zhang B-P (张百平), et al. Vertical zonation of mountain landscape: A review. Chinese Journal of Applied Ecology (应用生态学报), 2009, 20(7): 1617-1624 (in Chinese)