[1] |
郑飞鸽, 易桂花, 张廷斌, 等. 三江源植被碳利用率动态变化及其对气候的响应. 中国环境科学, 2020, 40(1): 401-413 [Zheng F-G, Yi G-H, Zhang T-B, et al. Study on spatiotemporal dynamics of vegetation carbon use efficiency and its response to climate factors in Three-River Headwaters Region. China Environmental Science, 2020, 40(1): 401-413]
|
[2] |
王斌, 李洁, 姜微微, 等. 草地退化对三江源区高寒草甸生态系统CO2通量的影响及其原因. 中国环境科学, 2012, 32(10):1764-1771 [Wang B, Li J, Jiang W-W, et al. Impacts of the rangeland degradation on CO2 flux and the underlying mechanisms in the Three-River Source Region on the Qinghai-Tibetan Pla-teau. China Environmental Science, 2012, 32(10): 1764-1771]
|
[3] |
王秀红, 郑度. 青藏高原高寒草甸资源的可持续利用. 资源科学, 1999, 21(6): 38-42 [Wang X-H, Zheng D. Sustainable use of alpine meadow grassland resources on the Qinghai-Tibetan Plateau. Resource Science, 1999, 21(6): 38-42]
|
[4] |
王启基, 周立, 赵新全. 高寒草甸草地畜牧业特点及对策的研究//刘季科, 王祖望. 高寒草甸生态系统第三集. 北京: 中国环境科学出版社, 1991: 275-284 [Wang Q-J, Zhou L, Zhao X-Q. Studies on characteristics and strategies of grassland animal husbandry of alpine meadow// Liu J-K, Wang Z-W, eds. Alpine Meadow Ecosystem Volume 3. Beijing: China Environmental Science Press, 1991: 275-284]
|
[5] |
陆晴, 吴绍洪, 赵东升. 1982—2013年青藏高原高寒草地覆盖变化及与气候之间的关系. 地理科学, 2017, 37(2): 292-300 [Lu Q, Wu S-H, Zhao D-S. Variations in alpine grassland cover and its correlation with climate variables on the Qinghai-Tibet plateau in 1982-2013. Scientia Geographica Sinica, 2017, 37(2): 292-300]
|
[6] |
Shao QQ, Cao W, Fan JW, et al. Effects of an ecological conservation and restoration project in the Three-River Source Region, China. Journal of Geographical Sciences, 2017, 27(2): 183-204
|
[7] |
王一博, 王根绪, 沈永平, 等. 青藏高原高寒区草地生态环境系统退化研究. 冰川冻土, 2005, 27(5): 633-640 [Wang Y-B, Wang G-X, Shen Y-P, et al. Degradation of the eco-environmental system in alpine meadow on the Tibetan Plateau. Journal of Glaciology and Geocryology, 2005, 27(5): 633-640]
|
[8] |
马玉寿, 郎百宁, 李青云, 等. 江河源区高寒草甸退化草地恢复与重建技术研究. 草业科学, 2002, 19(9): 1-4 [Ma Y-S, Lang B-N, Li Q-Y, et al. Study on rehabilitating and rebuilding technologies for degene-rated alpine meadow in the Changjiang and Yellow river source region. Pratacultural Science, 2002, 19(9): 1-4]
|
[9] |
Yang XD, Chen J. Plant litter quality influences the contribution of soil fauna to litter decomposition in humid tropical forests, southwestern China. Soil Biology & Biochemistry, 2009, 41: 910-918
|
[10] |
宋长青, 吴金水, 陆雅海, 等. 中国土壤微生物学研究10 年回顾. 地球科学进展, 2013, 28(10): 1087-1105 [Song C-Q, Wu J-S, Lu Y-H, et al. Advances of soil microbiology in the last decade in China. Advances in Earth Science, 2013, 28(10): 1087-1105]
|
[11] |
Hill GT, Mitkowski NA, Aldrich-Wolfe L, et al. Methods for assessing the composition and diversity of soil microbial communities. Applied Soil Ecology, 2000, 15: 25-36
|
[12] |
Wardle DA, Bardgett RD, Klironomos JN, et al. Ecological linkages between aboveground and belowground biota. Science, 2004, 304: 1629-1633
|
[13] |
Kiers ET, Duhamel M, Beesetty Y, et al. Reciprocal rewards stabilize cooperation in the mycorrhizal symbiosis. Science, 2011, 333: 880-882
|
[14] |
郭炜. 西北地区冬小麦普通根腐病和茎基腐病病原鉴定及种质资源抗性筛选. 硕士论文. 兰州: 甘肃农业大学, 2018 [Guo W. Studies on Pathogens and Resistance to Common Root Rot and Crown Rot on Winter Wheat in Northwest China. Master Thesis. Lanzhou: Gansu Agricultural University, 2018]
|
[15] |
丛丽丽, 康俊梅, 张铁军, 等. 苜蓿镰刀菌根腐病病原菌的分离鉴定与致病性分析. 草地学报, 2017, 25(4): 857-865 [Cong L-L, Kang J-M, Zhang T-J, et al. Identification and pathogenicity test of pathogenic fusarium of alfalfa root rot. Acta Agrestia Sinica, 2017, 25(4): 857-865]
|
[16] |
Malapi-Wight M, Salgado-Salazar C, Demers J, et al. Draft genome sequence of Dactylonectria macrodidyma, a plant-pathogenic fungus in the Nectriaceae. Genome Announcements, 2015, 3: 1-2
|
[17] |
Mangan SA, Schnitzer SA, Herre EA, et al. Negative plant-soil feedback predicts tree-species relative abundance in a tropical forest. Nature, 2010, 466: 752-755
|
[18] |
Hattenschwiler S, Tiunov AV, Scheu S. Biodiversity and litter decomposition in terrestrial ecosystems. Annual Review of Ecology, Evolution and Systematics, 2005, 36: 191-218
|
[19] |
丁玲玲, 祁彪, 尚占环, 等. 东祁连山亚高山草地土壤微生物功能群数量动态及其与土壤环境关系. 草业学报, 2007, 16(2): 9-18 [Ding L-L, Qi B, Shang Z-H, et al. Dynamics of different soil microbial physiological groups and their relationship to soil conditions under sub-alpine grasslands vegetation in the eastern Qilian Mountain. Acta Prataculturae Sinica, 2007, 16(2): 9-18]
|
[20] |
尚占环, 丁玲玲, 龙瑞军, 等. 江河源区退化高寒草地土壤微生物与地上植被及土壤环境的关系. 草业学报, 2007, 16(1): 34-40 [Shang Z-H, Ding L-L, Long R-J, et al. Relationship between soil microorga-nisms, above-ground vegetation, and soil environment of degraded alpine meadows in the headwater areas of the Yangtze and Yellow rivers, Qinghai-Tibetan Plateau. Acta Prataculturae Sinica, 2007, 16(1): 34-40]
|
[21] |
尹亚丽, 王玉琴, 李世雄, 等. 围封对退化高寒草甸土壤微生物群落多样性及土壤化学计量特征的影响. 应用生态学报, 2019, 30(1): 127-136 [Yin Y-L, Wang Y-Q, Li S-X, et al. Effects of enclosing on soil microbial community diversity and soil stoichiometric characteristics in a degraded alpine meadow. Chinese Journal of Applied Ecology, 2019, 30(1): 127-136]
|
[22] |
尹亚丽, 王玉琴, 鲍根生, 等. 退化高寒草甸土壤微生物及酶活性特征. 应用生态学报, 2017, 28(12) : 3881-3890 [Yin Y-L, Wang Y-Q, Bao G-S, et al. Characteristics of soil microbes and enzyme activities in different degraded alpine meadows. Chinese Journal of Applied Ecology, 2017, 28(12): 3881-3890]
|
[23] |
王玉琴, 尹亚丽, 李世雄. 不同退化程度高寒草甸土壤理化性质及酶活性分析. 生态环境学报, 2019, 28(6): 1108-1116 [Wang Y-Q, Yin Y-L, Li S-X. Physi-cochemical properties and enzymatic activities of alpine meadow at different degradation degrees. Ecology and Environmental Sciences, 2019, 28(6): 1108-1116]
|
[24] |
Gary B, 李希来, 陈刚. 三江源区自然景观、环境问题和管理. 西宁: 青海人民出版社, 2010: 192-205[Gary B, Xi L-L, Chen G. Landscape and Environment Science and Management in the Sanjiangyuan Region. Xi’ning: Qinghai People’s Press, 2010: 192-205]
|
[25] |
He D, Xiang XJ, He JS, et al. Composition of the soil fungi community is more sensitive to phosphorus than nitrogen addition in the alpine meadow on the Qinghai-Tibetan plateau. Biology & Fertility of Soils, 2016, 52: 1059-1072
|
[26] |
Zhou JZ, Xue K, Xie JP, et al. Microbial mediation of carbon-cycle feedbacks to climate warming. Nature Climate Change, 2012, 2: 106-110
|
[27] |
Li YM, Wang SP, Jiang LL, et al. Changes of soil microbial community under different degraded gradients of alpine meadow. Agriculture, Ecosystems & Environment, 2016, 222: 213-222
|
[28] |
Voriskova J, Baldrian P. Fungal community on decomposing leaf litter undergoes rapid successional changes. ISME Journal, 2013, 7: 477-486
|
[29] |
Hooper DU, Bignell DE, Brown VK, et al. Interactions between aboveground and belowground biodiversity in terrestrial ecosystems: Patterns, mechanisms, and feedbacks. BioScience, 2000, 50: 1049-1061
|
[30] |
Probst CM, Ridgway HJ, Jaspers MV, et al. Pathogenicity of Ilyonectria liriodendri and Dactylonectria macrodidyma propagules in grapevines. European Journal of Plant Pathology, 2019, 154: 405-421
|
[31] |
刘勇, 张雅雯, 南志标, 等. 天然草地管理措施对植物病害的影响研究进展. 生态学报, 2016, 36(14): 4211-4220 [Liu Y, Zhang Y-W, Nan Z-B, et al. Progress of research into the effects of native grassland mana-gement practices on plant disease. Acta Ecologica Sinica, 2016, 36(14): 4211-4220]
|
[32] |
Wennstrom A, Ericson L. Variation in disease incidence in grazed and ungrazed sites for the system pulsatilla pratensispuccinia pulsatillae. Oikos, 1991, 60: 35-39
|
[33] |
Chen XY, Daniell TJ, Neilson R, et al. Microbial and microfaunal communities in phosphorus limited, grazed grassland change composition but maintain homeostatic nutrient stoichiometry. Soil Biology & Biochemistry, 2014, 75: 94-101
|
[34] |
Newsham KK, Hopkins DW, Carvalhais LC, et al. Relationship between soil fungal diversity and temperature in the maritime Antarctic. Nature Climate Change, 2016, 6: 182-186
|
[35] |
Tedersoo L, Bahram M, Polme S, et al. Fungal biogeo-graphy: Global diversity and geography of soil fungi. Science, 2014, 346: 1256688
|
[36] |
Bahram M, Polme S, Koljalg U, et al. Regional and local patterns of ectomycorrhizal fungal diversity and community structure along an altitudinal gradient in the Hyrcanian forests of northern Iran. New Phytologist, 2012, 193: 465-473
|
[37] |
Rousk J, Brookes PC, Baath E. Contrasting soil pH effects on fungal and bacterial growth suggest functional redundancy in carbon mineralization. Applied and Environmental Microbiology, 2009, 75: 1589-1596
|
[38] |
Cui YX, Bing HJ, Fang LC, et al. Diversity patterns of the rhizosphere and bulk soil microbial communities along an altitudinal gradient in an alpine ecosystem of the eastern Tibetan Plateau. Geoderma, 2019, 338: 118-127
|
[39] |
Zhang Y, Cao CY, Peng M, et al. Diversity of nitrogen-fixing, ammonia-oxidizing, and denitrifying bacteria in biological soil crusts of a revegetation area in Horqin Sandy Land, northeast China. Ecological Engineering, 2014, 71: 71-79
|
[40] |
石国玺, 王文颖, 蒋胜竞, 等. 黄帚橐吾种群扩张对土壤理化特性与微生物功能多样性的影响. 植物生态学报, 2018, 42(1): 126-132 [Shi G-X, Wang W-Y, Jiang S-J, et al. Effects of the spreading of Ligularia virgaurea on soil physicochemical property and microbial functional diversity. Chinese Journal of Plant Ecology, 2018, 42(1): 126-132]
|