LI Wendong,JIANG Yue,LI Bo,et al.Intervention Intensity of Human Activity on Potential Natural Vegetation in the Hekouzhen-Longmen Region[J].Research of Soil and Water Conservation,2023,30(05):283-293.[doi:10.13869/j.cnki.rswc.2023.05.051.]
人类活动对河龙区间潜在自然植被的干预强度
- Title:
- Intervention Intensity of Human Activity on Potential Natural Vegetation in the Hekouzhen-Longmen Region
- 文章编号:
- 1005-3409(2023)05-0283-11
- Keywords:
- potential natural vegetation; intervention intensity; comprehensive and sequential classification system; Hekouzhen-Longmen Region; human activity
- 分类号:
- Q948
- 文献标志码:
- A
- 摘要:
- [目的]探究黄河中游河龙区间潜在自然植被(PNV)的时空变化规律,查明人类活动对该区域PNV的干预程度,可为区域生态系统恢复、重建和可持续发展提供理论参考。[方法]基于河龙区间1960—2017年气象数据和1990—2018年4期土地利用数据,利用GIS技术和综合顺序分类系统(CSCS)模拟并分析了河龙区间1960—2017年PNV的时空变化特征,并探讨1990年以来人类活动对PNV的干预强度。[结果]河龙区间稳定的PNV类型按面积由大到小排序为:暖温微干温带典型草原类、暖温微润森林草原类、微温微润草甸草原类、微温微干温带典型草原类。不同年代各PNV类型重心发生不同程度的迁移。土地利用类型以草地、耕地和林地为主。草地、林地、建设用地面积呈增长趋势,而耕地和其他地类呈减少趋势。各地类重心也在不断发生变化。受人类活动影响,草原类PNV的30.9%~36.2%和11.4%~18.5%面积分别转变为耕地和林地,森林草原类PNV的19.0%~32.6%面积转变为耕地,潜在草地区转变为林地的面积比例逐年增加。[结论]人类活动对PNV的干扰动态变化度在1990—2000年和2010—2018年较大,尤其是2010—2018年,且现有林地是否持续存活需要多关注。
- Abstract:
- [Objective] Exploring the temporal and spatial changes of Potential Natural Vegetation(PNV)and identifying the intervention intensity of human activity on PNV in the Hekouzhen-Longmen Region of the middle reaches of the Yellow River can provide a theoretical reference for regional ecosystem restoration, reconstruction and sustainable development. [Methods] Based on meteorological data from 1960 to 2017 and land use data from 1990 to 2018 in the Hekouzhen-Longmen Region, we used GIS technology and Comprehensive and Sequential Classification System(CSCS)model to simulate and analyze the temporal and spatial variation characteristics of PNV in the Hekouzhen-Longmen Region from 1960 to 2017, and explored the intervention intensity of human activity on PNV since 1990. [Results] The stable PNV types in the Hekouzhen-Longmen Region were sorted in descending order of area as follows: Warm temperate-semiarid warm temperate typical steppe, Warm temperate-subhumid forest steppe, Cool temperate-subhumid meadow steppe, Cool temperate-semiarid temperate typical steppe. Different degrees of centroids of PNV types had shifted in different ages. The center of gravity of PNV types had migrated in different degrees in different ages. The land use types were mainly grassland, cultivated land and forestland. The areas of grassland, forestland and construction land showed an increasing trend, while the areas of cultivated land and other land types showed a decreasing trend. The center of gravity of each land use type was also changing. Affected by human activity, 30.9%~36.2% and 11.4%~18.5% of steppe PNV were transformed into cultivated land and forest land respectively, and 19.0%~32.6% of forest-steppe PNV was transformed into cultivated land. The proportion of potential grassland area converted to forestland was increasing year by year, [Conclusion] The dynamic change degree of human activity' interference to PNV was larger in 1990—2000 and 2010—2018, especially in 2010—2018, and more attention should be paid to whether the existing forestland can survive continuously.
参考文献/References:
[1] Chen X, Yu L, Du Z R, et al. Distribution of ecological restoration projects associated with land use and land cover change in China and their ecological impacts[J]. Science of the Total Environment, 2022,825:153938.
[2] 张颖,章超斌,王钊齐,等.气候变化与人为活动对三江源草地生产力影响的定量研究[J].草业学报,2017,26(5):1-14.
[3] Reynolds K M, Hessburg P F. Decision support for integrated landscape evaluation and restoration planning [J]. Forest Ecology and Management, 2005,207(1/2):263-278.
[4] Kaplan J O, Krumhardt K M, Zimmermann N. The prehistoric and preindustrial deforestation of Europe[J]. Quaternary Science Reviews, 2009,27/28:3016-3034.
[5] 于贵瑞,谢高地,王秋凤,等.西部地区植被恢复重建中几个问题的思考[J].自然资源学报,2002,17(2):216-220.
[6] Tüxen R. Die heutige potentille natuerliche vegetation als Gegenst vegetation skartierung[J]. Angew, Pflanzensoziologie, 1956,13:5-42.
[7] 杜怀玉,赵军,师银芳,等.气候变化下中国潜在植被演替及其敏感性[J].生态学杂志,2018,37(5):1459-1466.
[8] Hickler T, Vohland K, Feehan J, et al. Projecting the future distribution of European potential natural vegetation zones with a generalized, tree species-based dynamic vegetation model [J]. Global Ecology and Biogeography, 2012,21(1):50-63.
[9] Wolf A, Callaghan T V, Larson K. Future changes in vegetation and ecosystem function of the Barents Region [J]. Climatic Change, 2008,87(1):51-73.
[10] Somodi I, Molnár Z, Czúcz B, et al. Implementation and application of multiple potential natural vegetation models: A case study of Hungary[J]. Journal of Vegetation Science, 2017,28(6):1260-1269.
[11] Peng S Z, Li Z. Potential land use adjustment for future climate change adaptation in revegetated regions [J]. Science of the Total Environment, 2018,639:476-484.
[12] 赵传燕,冯兆东,南忠仁,等.黄土高原祖厉河流域潜在植被分布模拟研究[J].地理学报,2007,62(1):52-61.
[13] 韩庆功,彭守璋.黄土高原潜在自然植被空间格局及其生境适宜性[J].水土保持学报,2021,35(5):188-193.
[14] Shi H, Shao M A. Soil and water loss from the Loess Plateau in China [J]. Journal of Arid Environments, 2000,45(1):9-20.
[15] 韩鹏,王艺璇,李岱峰.黄河中游河龙区间河川基流时空变化及其对水土保持响应[J].应用基础与工程科学学报,2020,28(3):505-521.
[16] Yuan Q Z, Wu S H, Dai E, et al. NPP vulnerability of the potential vegetation of China to climate change in the past and future [J]. Journal of Geographical Sciences, 2017,27(2):131-142.
[17] 张静,张丽,韩瑞丹,等.中东亚干旱区土地覆盖变化和人类占用强度变化特征[J].草业科学,2017,34(5):975-987.
[18] 修丽娜.基于CSCS模型的中国潜在自然植被时空分布特征研究[D].兰州:兰州大学,2014.
[19] Sun Z G, Sun C M, Wei Z, et al. Classification and net primary productivity of the Southern China's grasslands ecosystem based on improved comprehensive and sequential classification system(CSCS)approach [J]. Journal of Integrative Agriculture, 2014,13(4):893-903.
[20] 林慧龙,范迪,冯琦胜,等.草地综合顺序分类法研究新热点:2008—2020年回顾与展望[J].草业学报,2021,30(10):201-213.
[21] Zhao J, Du H Y, Shi Y F, et al. A GIS simulation of potential vegetation in China under different climate scenarios at the end of the 21 st century [J]. Contemporary Problems of Ecology, 2017,10(3):315-325.
[22] 任继周,胡自治,牟新待,等.草原的综合顺序分类法及其草原发生学意义[J].中国草原,1980(1):12-24.
[23] Lin H L, Zhao J, Liang T G, et al. A classification indices-based model for net primary productivity(NPP)and potential productivity of vegetation in China[J]. International Journal of Biomathematics, 2012,5(3):1260009.
[24] 张美玲,陈全功,蒋文兰.不同草地类型净初级生产力(NPP)模拟及其敏感性分析[J].干旱区地理,2021,44(2):369-378.
[25] Liu X N, Zhang B S, Henry B, et al. Assessing the impact of historical and future climate change on potential natural vegetation types and net primary productivity in Australian grazing lands [J]. the Rangeland Journal, 2017,39(4):387-400.
[26] 任正超,朱华忠,史华,等.最后间冰期至未来2070s中国潜在自然植被时空分布格局及其对气候变化的响应[J].自然资源学报,2020,35(6):1484-1498.
[27] 李飞,赵军,赵传燕,等.中国潜在植被空间分布格局[J].生态学报,2008,28(11):5347-5355.
[28] 赵军,马小平,魏伟.近50年黑河流域潜在植被的演替及生态环境变化研究[J].草业学报,2014,23(5):61-68.
[29] 李飞,赵军,赵传燕,等.中国西北干旱区潜在植被模拟与动态变化分析[J].草业学报,2011,20(4):42-50.
[30] 刘华民,吴绍洪,郑度,等.潜在自然植被研究与展望[J].地理科学进展,2004,23(1):62-70.
[31] Han Q G, Ding Y X, Peng S Z. Sustainable and cost-effective vegetation restoration framework under climate change [J]. Forest Ecology and Management, 2021,496:119436.
[32] 张萍,蔡强国,郑明国,等.黄河河口—龙门区间降雨时空分布特征及其与流域产沙的关系[J].水土保持通报,2020,40(4):25-31.
[33] 宁珍,高光耀,傅伯杰.黄河河龙区间输沙变化特征及归因分析[J].水土保持研究,2022,29(3):38-42.
[34] 付金霞,张鹏,郑粉莉,等.河龙区间近55 a降雨侵蚀力与河流输沙量动态变化分析[J].农业机械学报,2016,47(2):185-192.
[35] 黄萱,丁继辉,邹钰文,等.黄河中游河龙区间侵蚀产沙对景观特征的非线性响应[J].水土保持学报,2021,35(6):88-94.
[36] 董亚维,吴永红,马卫星,等.基于遥感监测的河龙区间水土保持效果分析[J].水资源与水工程学报,2012,23(1):157-160.
[37] 胡自治,高彩霞.草原综合顺序分类法的新改进Ⅰ类的划分指标及其分类检索图[J].草业学报,1995,4(3):1-7.
[38] 郭柯,方精云,王国宏,等.中国植被分类系统修订方案[J].植物生态学报,2020,44(2):111-127.
[39] 任继周.分类、聚类与草原类型[J].草地学报,2008,16(1):4-10.
[40] 蒋好雨,陈荣蓉,杨朝现,等.西部平原区生态用地时空动态特征及环境效应[J].水土保持研究,2021,28(2):203-209.
[41] 杨爱民,朱磊,陈署晃,等.1975—2015年玛纳斯河流域土地利用变化的地学信息图谱分析[J].应用生态学报,2019,30(11):3863-3874.
[42] 危小建,赵莉,程朋根,等.中国土地利用与生态服务价值空间动态研究:以地级及以上城市为例[J].水土保持研究,2022,29(4):370-376.
[43] Liang T G, Feng Q S, Cao J J, et al. Changes in global potential vegetation distributions from 1911 to 2000 as simulated by the Comprehensive Sequential Classification System approach [J]. Chinese Science Bulletin, 2012,57(11):1298-1310.
[44] 邹德富,冯琦胜,王莺,等.基于GIS的甘南地区草原综合顺序分类研究[J].草业科学,2011,28(1):27-32.
[45] Shi Y F, Zhao J, Grace P, et al. Uncertainties on the GIS based potential natural vegetation simulation using Comprehensive and Sequential Classification System [J]. Geografiska Annaler:Series A, Physical Geography, 2020,103(2):186-198.
[46] 车彦军,赵军,师银芳,等.基于CSCS和RegCM3模型的21世纪末中国潜在植被[J].生态学杂志,2014,33(2):447-454.
[47] 修丽娜,冯琦胜,梁天刚.基于CSCS方法的甘南自然植被NDVI时空分布特征研究[J].草业学报,2013,22(4):239-246.
[48] Peng S Z, Yu K L, Li Z, et al. Integrating potential natural vegetation and habitat suitability into revegetation programs for sustainable ecosystems under future climate change [J]. Agricultural and Forest Meteorology, 2019,269:270-284.
备注/Memo
收稿日期:2022-07-14 修回日期:2022-10-14
资助项目:国家自然科学基金(41807070; U2243210)
第一作者:李文栋(1998—),男,山东沂水人,在读硕士研究生,主要从事生态水文研究。E-mail:lwd19980908@163.com
通信作者:付金霞(1978—),女,甘肃靖远人,博士,副教授,主要从事气候变化、土地利用覆被变化与土壤侵蚀研究。E-mail:fujinxia405@nwsuaf.edu.cn