[1]LUO Zhengpeng,XIONG Kangning,XV Liuxing.Study on the Role of Biological Soil Crust in Ecological Restoration and Its Enlightenment to the Control of Rocky Desertification[J].Research of Soil and Water Conservation,2020,27(01):394-404.
Copy
Study on the Role of Biological Soil Crust in Ecological Restoration and Its Enlightenment to the Control of Rocky Desertification
Research of Soil and Water Conservation[ISSN 1005-3409/CN 61-1272/P] Volume:
27
Number of periods:
2020 01
Page number:
394-404
Column:
Public date:
2020-02-20
- Title:
- Study on the Role of Biological Soil Crust in Ecological Restoration and Its Enlightenment to the Control of Rocky Desertification
- Keywords:
- biological soil crust; karst; eco-environmental remediation; controlling rocky desertification
- CLC:
- Q948.11
- DOI:
- -
- Abstract:
- The southwest karst is the core area of karst, China. Due to the large area of exposed carbonate, altitude difference, geomorphology and climate factors, the ecosystems are very fragile. The main problems of karst ecosystems in southwest China are serious soil erosion, soil degradation, biodiversity degradation and rocky desertification. In view of the above issues, the conventional measurements such as replanting forest and grass are difficult to implement. As a pioneer in the desert habitat, biological soil crust has the positive function of ecological restoration in soil system, hydrology system and biological system. In this paper, the problem of ecological degradation in Karst area of southwest China and ecological restoration function of biological soil crust have been reviewed, base on this, we hope these reviews will benefit to stable and sustainable development of ecosystem and ecological remediation in the karst area.
- References:
-
[1] 熊康宁,黎平,周忠发.喀斯特石漠化的遥感—GIS典型研究:以贵州省为例[M].北京:地质出版社,2002.
[2] 熊康宁,李晋,龙明忠.典型喀斯特石漠化治理区水土流失特征与关键问题[J].地理学报,2012,67(7):878-888.
[3] West N E. Structure and function of microphytic soil crusts in wild-land ecosystems of arid to semi-arid regions[J]. Advancesin Eco-Logical Research, 1990,20:179-223.
[4] Eldridge D J, Greene R. Microbiotic soil crusts:A view of their roles in soil and ecological processes in the range lands of Australia[J]. Australian Journal of Soil Research, 1994,32(3):389-415.
[5] Patrick E. Researching crusting soils:Themes, trends, recent developments and implications for managing soil and water resources in dry areas[J]. Progress in Physical Geography, 2002,26(3):442-461.
[6] Housman D C, Yeager C M, Darby B J, et al. Heterogeneity of soil nutrients and subsurface biota in a dryland ecosystem[J]. Soil Biology & Biochemistry, 2007,39(8):2138-2149.
[7] Wang W, Liu Y, Li D, et al. Feasibility of cyanobacterial inoculation for biological soil crusts formation in desert area[J]. Soil Biology & Biochemistry, 2009,41(5):926-929.
[8] Cole D N. Trampling disturbance and recovery of cryptogamic soil crusts in grand canyon national park[J]. Great Basin Naturalist, 1990,50(4):321-325.
[9] Friedmann E I, Ocampo R. Endolithic blue-green algae in the dry valleys:Primary producers in the antarctic desert ecosystem[J]. Science, 1976,193(4259):12-47.
[10] Gilad E, Von H J, Provenzale A, et al. Ecosystem engineers:From pattern formation to habitat creation[J]. Physical Review Letters, 2004,93(9):1-4.
[11] 高丽倩.黄土高原生物结皮土壤抗水蚀机理研究[D].陕西杨凌:中国科学院教育部水土保持与生态环境研究中心,2017.
[12] 卜楠,朱清科,王蕊,等.陕北黄土区生物土壤结皮抗冲性研究[J].北京林业大学学报,2009,31(5):96-101.
[13] Mallen-Cooper M, Eldridge, D J, et al. Livestock grazing and aridity reduce the functional diversity of biocrusts[J]. Plant and Soil, 2017,429(1/2):175-185.
[14] Tisdall J M, Oades J M. Organic matter and water stable aggregates in soils[J]. Journal of Soil Science, 1982,33(2):146-163.
[15] Greene R S B, Charires C J. The effect of fire on the soil of the degraded semiarid woodland.Ⅰ. Cryptogam cover and physical microphological properties[J]. Aust J Soil Res, 1990,28(5):755-777.
[16] Issa O M, Défarge C, Bissonnais Y L, et al. Effects o f the inoculation of cyanobacteria on the microstructure and the structural stability of a tropical soil[J]. Plant & Soil, 2007,290(1/2):209-219.
[17] 张元明.荒漠地表生物土壤结皮的微结构及其早期发育特征[J].科学通报,2005,50(1):42-47.
[18] 郑娇莉,李双双,彭成荣,等.干燥对人工生物土壤结皮固氮酶活性恢复过程的影响[J].中国科学:生命科学,2017,47(7):73-83.
[19] Chamizo S, Cantón Y, Miralles I, et al. Biological soil crust development affects physicochemical characteristics of soil surface in semiarid ecosystems[J]. Soil Biology and Biochemistry, 2012,49:96-105.
[20] Harper K T, Pendleton R L. Cyanobacteria and cyanolichens:Can they enhance availability of essential minerals for higher plants[J]. Great Basin Naturalist, 1993,53(1):59-72.
[21] 张鹏,李新荣,张志山,等.腾格里沙漠东南缘生物土壤结皮的固氮潜力[J].应用生态学报,2012,23(8):2157-2164.
[22] Rogers S L, Burns R G. Changes in aggregate stability, nutrient status, indigenous microbial populations, and seedling emergence, following inoculation of soil with Nostoc muscorum[J]. Biology and Fertility of Soils, 1994,18(3):209-215.
[23] Harper K T, Belnap J. The influence of soil biological crusts on mineral uptake by associated vascular plants[J]. Journal of Arid Environments, 2001,47(3):347-357.
[24] Bowker M A, Belnap J, Davidson D W, et al. Evidence for micro nutrient limitation of biological soil crusts:Importance to arid-lands restoration[J]. Ecological Applications, 2005,15(6):1941-1951.
[25] Torgway D J, Ludwig J A. Vegetation and soil patterning in semi-arid mulga lands of eastern Australia[J]. Australian Ecology, 1990,15(1):23-34.
[26] 胡春香,张德禄,刘永定,等.荒漠藻结皮的胶结机理[J].科学通报,2002,47(12):931-937.
[27] Lebrun J D, Trinsoutrotgattin I, Vinceslasakpa M, et al. Assessing impacts of copper on soil enzyme activities in regard to their natural spatiotemporal variation under long-term different land uses[J]. Soil Biology & Biochemistry, 2012,49(6):150-156.
[28] Zhang W, Zhang G, Liu G, et al. Bacterial diversity and distribution in the southeast edge of the Tengger Desert and their correlation with soil enzyme activities[J].环境科学学报:英文版,2012,24(11):2004-2011.
[29] Miralles I, Domingo F, Cantón Y, et al. Hydrolase enzyme activities in a successional gradient of biological soil crusts in arid and semi-arid zones[J]. Soil Biology & Biochemistry, 2012,53:124-132.
[30] 边丹丹,廖超英,孙长忠,等.黄土丘陵区土壤生物结皮对土壤微生物分布特征的影响[J].干旱地区农业研究,2011,29(4):109-114.
[31] 刘梅,赵秀侠,詹婧,等.铜陵铜尾矿废弃地生物土壤结皮中的蓝藻多样性[J].生态学报,2011,31(22):6886-6895.
[32] 周小泉,刘政鸿,杨永胜,等.毛乌素沙地3种植被下苔藓结皮的土壤理化效应[J].水土保持研究,2014,21(6):340-344.
[33] Kidron G J. Analysis of dew precipitation in three habitats within a small arid drainage basin, Negev Highlands, Israel[J]. Atmospheric Research, 2000,55(3):257-270.
[34] Kidron G J, Aaron Y, Avinoam D. Dew variability within a small arid drainage basin in the Negev Highlands, Israel[J]. Quarterly Journal of the Royal Meteorological Society, 2010,126(562):63-80.
[35] Li X Y. Effects of gravel and sand mulches on dew deposition in the semiarid region of China[J]. Journal of Hydrology, 2002,260(1/4):151-160.
[36] Li X R, Kong D S, Tan H J, et al. Changes in soil land in vegetation following stabilisation of dune in southeastern fringe of the Tengger desert, China[J]. Plantand Soil, 2007,300(1):221-231.
[37] Darby B J, Neher D A. Soil nematode communities are ecologically more mature beneath late-than early successional stage biological soil crusts[J]. Applied Soil Ecology, 2007,35(1):203-212.
[38] Liu L C, Li S Z, Duan Z H. Effects of microbiotic crusts on dew deposition in the stored vegetation area at shapotou, north west China[J]. Journal of Hydrology, 2006,328(1/2):331-337.
[39] Warren S D. Synopsis:Influence of biological soil crusts on arid land hydrology and soil stability[M]∥Springer-Verlag Berlin Heidelbergbiological Soil Crusts:Structure, Function, and Management, 2001.
[40] Pérez F L. Microbiotic crusts in the high equatorial Andes, and their influence on paramo soils[J]. Catena, 1997,31(3):173-198.
[41] Bisdom E B A, Dekker L W, Schoute J F T. Water repellency of sieve fractions from sandy soil sand relationships with organic material and soil structure[J]. Geoderma, 1993,56(1):105-118.
[42] Danin A. Plants of Desert Dunes[M]. Berlin: Springer-Verlag Berlin Heidelberg, 1996.
[43] Eldridge D J, Tozer M E, Slangen S. Soil hydrology is independent of microphytic crust cover:Further evidence from a wooded semiarid Australian range land[J]. Arid Soil Research and Rehabilitation, 1997,11(2):113-126.
[44] 李新荣,张元明,赵允格.生物土壤结皮研究:进展、前沿与展望[J].地球科学进展,2009,24(1):11-24.
[45] 刘艳梅,李新荣,赵昕,等.生物土壤结皮对荒漠土壤线虫群落的影响[J].生态学报,2013,33(9):2816-2824.
[46] Loria M, Herrnstadt I. Moss Capsules as Food of the Harvester Ant, Messor[J]. Bryologist, 1980,83(4):524-525.
[47] Li X R, Chen Y W, Jia R L. Biological soil crusts:A significant food source for insects in the arid desert ecosystems[J]. Journal of Desert Research, 2008,28(2):245-248.
[48] Li X R, Jia X H, Zerb S. Effects of biological soil crusts on seed bank, germination and establishment of two annual plant species in the Tengger desert(N China)[J]. Plant and Soil, 2005,277(1):375-385.
[49] Su Y G, Li X R, Cheng Y W, et al. Effects of biological soil crusts on emergence of desert vascular plants in North China[J]. Plant Ecology, 2007,191(1):11-19.
[50] Johansen J R. Cryptogamic crusts of semiarid and arid lands of north America [J]. Journal of Phycology, 1993,29(2):140-147.
[51] Jeffries D L, Klopatek J M. Effects of Grazing on the Vegetation of the Blackbrush Association[J]. Journal of Range Management, 1987,40(5):390-392.
[52] Carleton T J. Variation in terricolous bryophyte and macrolichen vegetation along primary gradients in Canadian boreal forests[J]. Journal of Vegetation Science, 1990,1(5):585-594.
[53] Lesica P, Shelley J S. Effects of cryptogamic soil crust on the population dynamics of Arabis fecunda[J]. American Midllde Naturist, 1992,128(1):53-60.
[54] Harper K T, St Clair L L. Cryptogamic soil crusts on arid and semiarid rangelands in Utah[C]∥ Effects on seedling establishment and soil stability. Final Rept Bureau Land Management, Utah State Office, Salt Lake City, 1985.
[55] 苏延桂,李新荣,陈应武,等.生物土壤结皮对荒漠土壤种子库和种子萌发的影响[J].生态学报,2007,27(3):938-946.
[56] Xiao B, Zhao Y, Wang H, et al. Natural recovery of moss-dominated biological soil crusts after surface soil removal and their long-term effects on soil water conditions in a semi-arid environment[J]. Catena, 2014,120:1-11.
[57] Li X R, Zhou H Y, Wang X P, et al. The effects of sand stabilization and revegetation on cryptogam species diversity and soil fertility in the Tengger Desert, Northern China[J]. Plant and Soil, 2003,251(2):237-245.
[58] 李新荣,谭会娟,回嵘.中国荒漠与沙地生物土壤结皮研究[J].科学通报,2018,63(23):16-30.
[59] 卜崇峰,蔡强国,张兴昌.土壤结皮的发育特征及其生态功能研究述评[J].地理科学进展,2008,27(2):26-31.
[60] Coxson D S. Biological soil crusts:structure, function, and management[J]. Biological Conservatin, 2002,108(1):129-130.
[61] 张元明,王雪芹.荒漠地表生物土壤结皮形成与演替特征概述[J].生态学报,2009,30(16):4484-4492.
[62] 张元明,陈晋,王雪芹.古尔班通古特沙漠生物结皮的分布特征[J].地理学报,2005,60(1):53-60.
[63] 吴沛沛,饶本强,郝宗杰.高温培养条件下爪哇伪枝藻的生理特性和超微结构特征[J].水生生物学报,2012,36(4):735-743.
[64] 丛立双,刘惠荣,王瑞刚.浑善达克沙地生物土壤结皮细菌群落特征[J].内蒙古农业大学学报:自然科学版,2010,31(3):168-172.
[65] Wu J G, Wang J F, Zhang X H, et al. AgyrB-targeted PCR for rapid identification of Paenibacillus mucilaginous [J]. Applied Microbiology & Biotechnology, 2010,87(2):739-747.
[66] Liu W, Xu X, Wu X, et al. Decomposition of silicate minerals by bacillus mucilaginosus in liquidculture[J]. Environmental Geochemistry & Health, 2006,28(1/2):133-140.
[67] 聂华丽,吴楠,梁少民.不同沙埋深度对刺叶墙藓植株碎片生长的影响[J].干旱区研究,2006,23(1):66-70.
[68] 武显维,丁朝华,康宁.湿地甸灯醉切茎繁殖研究[J].武汉植物研究,1996,14(1):82-88.
[69] Wasley J. The effect of climate change on Antarctic terrestrial flora[D]. University of Wollongong Thesis Collection, 2004.
[70] 王中生,安树青,方炎明.苔藓植物生殖生态学研究[J].生态学报,2003,23(11):2444-2452.
[71] 卜崇峰,杨建振,张兴.毛乌素沙地生物结皮层藓类植物培育试验研究[J].中国沙漠,2011,31(4):937-941.
[72] Hui R, Zhao R, Liu L, et al. Effects of UV-B, water deficit and their combination on Bryum argenteum plants:a comprehensive Russian journal on modern phytophysiology[J]. Russian Journal of Plant Physiology, 2016,63(2):216-223.
[73] Lan S, Wu L, Zhang D. Desiccation provides photosynthetic protection for crust cyanobacteria microcoleus vaginatus from high temperature. [J]. Physiologia Plantarum, 2014,152(2):345-354.
[74] Lan S B, Wu L, Zhang D L, et al. Effects of drought and salt stresses on man-made cyanobacterial crusts. [J]. European Journal of Soil Biology, 2010,46(6):381-386.
[75] 刘应迪,李菁,陈军.两种五倍子蚜虫冬寄主藓类植物的光合特性及其与光照、温度和植物体水分含量变化的关系[J].应用生态学报,2000,11(5):687-692.
[76] Rossi F, Li H, Liu Y. Cyanobacterial inoculation(cyanobacterisation):Perspectives for the development of a standardized multifunctional technology for soil fertilization and desertification reversal[J]. Earth-Science Reviews, 2017,171,28-43.
[77] Chongfeng B, Shufang W, Yongsheng Y. Identification of factors influencing the restoration of cyanobacteria-dominated biological soil crusts[J]. Plos One, 2014,9(3):e90049.
[78] 杨永胜,冯伟,袁方.快速培育黄土高原苔藓结皮的关键影响因子[J].水土保持学报,2015,29(4):289-294.
[79] 王春.喷播苔藓结皮培育恢复技术研究[D].陕西杨凌:西北农林科技大学,2017.
[80] Chan-Ho P, Rong L X, Yang Z. Rapid develo pment of cyanobacterial crust in the field for combating desertification[J]. Plos One, 2017,12(6), e0179903.
[81] Chen L, Xie Z, Hu C. Man-made desert algal crusts as affected by environmental factors in Inner Mongolia, China[J]. Journal of Arid Environments, 2006,67(3):521-527.
[82] 兰安军,张百平,熊康宁.黔西南脆弱喀斯特生态环境空间格局分析[J].地理研究,2003,22(6):733-741.
[83] 钱家忠,汪家权,吴剑锋.徐州张集水源地裂隙岩溶水化学特征及影响因素[J].环境科学研究,2003,16(2):23-26.
[84] 曾晓燕,牟瑞芳,许顺国.岩溶生态脆弱性研究[J].环境科学与管理,2006,31(1):86-88.
[85] 张殿发,王世杰,李瑞玲.贵州省喀斯特山区生态环境脆弱性研究[J].地理学与国土研究,2002,18(1):77-79.
[86] 魏亚伟,苏以荣,陈香碧,等.桂西北喀斯特土壤对生态系统退化的响应[J].应用生态学报,2010,21(5):1308-1314.
[87] 赵其国,黄国勤,马艳芹.中国南方红壤生态系统面临的问题及对策[J].生态学报,2013,33(24):7615-7622.
[88] 蒋忠诚,曹建华,杨德生,等.西南岩溶石漠化区水土流失现状与综合防治对策[J].中国水土保持科学,2008,6(1):37-42.
[89] 尹辉,蒋忠诚,罗为群,等.西南岩溶区水土流失与石漠化动态评价研究[J].水土保持研究,2011,18(1):66-70.
[90] 王世杰.喀斯特石漠化:中国西南最严重的生态地质环境问题[J].矿物岩石地球化学通报,2003,22(2):120-126.
[91] 袁道先.岩溶石漠化问题的全球视野和我国的治理对策与经验[J].草业科学,2008,25(9):19-25.
[92] 张光辉,张新平,张丽.草地畜牧业是改变岩溶地区贫穷面貌的首选产业[J].草业科学,2008,25(9):83-86.
[93] 聂跃平.碳酸盐岩性因素控制下喀斯特发育特征:以黔中南为例[J].中国岩溶,1994,13(1):31-36.
[94] 唐梅荣,赵振峰,李宪文,等.多缝压裂新技术研究与试验[J].石油钻采工艺,2010,32(2):71-74.
[95] 王世杰,李阳兵,李瑞玲.喀斯特石漠化的形成背景、演化与治理[J].第四纪研究,2003,23(6):657-666.
[96] 蒋忠诚,王瑞江,裴建国,等.我国南方表层岩溶带及其对岩溶水的调蓄功能[J].中国岩溶,2001,20(2):106-110.
[97] 冯国章.极限水文干旱历时概率分布的解析与模拟研究[J].地理学报,1994,61(5):457-466.
[98] 李宏,姜凤国.聚焦西南大旱[J].地理教育,2010,7(5):63.
[99] 李双成,吴绍洪,戴尔阜.生态系统响应气候变化脆弱性的人工神经网络模型评价[J].生态学报,2005,25(3):621-626.
[100] 杨汉奎.喀斯特环境质量变异[M].贵阳:贵州科学技术出版社,1994.
[101] Lucrezi S, Saayman M, Merwe P V D. Influence of infrastructure development on the vegetation community structure of coastal dunes:Jeffreys Bay, South Africa[J]. Journal of Coastal Conservation, 2014,18(3):193-211.
[102] 于维莲,董丹,倪健.中国西南山地喀斯特与非喀斯特森林的生物量与生产力比较[J].亚热带资源与环境学报,2010,05(2):25-30.
[103] 贵州省环境保护局.贵州珍稀濒危植物[M].北京:中国环境科学出版社,1989.
[104] 韦锋.桂林会仙喀斯特湿地生物多样性及保护研究[D].广西桂林:广西师范大学,2010.
[105] 傅伯杰,刘国华,陈利顶,等.中国生态区划方案[J].生态学报,2001,21(1):1-6.
[106] 姚长宏,蒋忠诚,袁道先.西南岩溶地区植被喀斯特效应[J].地球学报,2001,22(2):159-164.
[107] 盛茂银,熊康宁,崔高仰,等.贵州喀斯特石漠化地区植物多样性与土壤理化性质[J].生态学报,2015,35(2):434-448.
[108] Tang C Q, Li Y H, Zhang Z Y.2010. Species diversity patterns in natural secondary plant communities and man-made forests in a subtropical mountainous karst area, Yunnan, SW China[J]. Mountain Research and Development, 2010,30(3):244-251.
[109] 樊云龙,熊康宁,苏孝良,等.喀斯特高原不同植被演替阶段土壤动物群落特征[J].山地学报,2010,28(2):226-233.
[110] 周文龙,熊康宁,龙健,等.喀斯特石漠化综合治理区表层土壤有机碳密度特征及区域差异[J].土壤通报,2011,42(5):1131-1137.
[111] 吴红宇,马凤娟.西南喀斯特地区农业生态补偿机制初探[J].农业资源与环境学报,2010,27(1):15-18.
[112] 侯慧,董坤,杨智仙,等.连作障碍发生机理研究进展[J].土壤,2016,48(6):1068-1076.
[113] 李冰,张朝晖.喀斯特石漠结皮层藓类物种多样性及在石漠化治理中的作用研究[J].中国岩溶,2009,28(1):55-60.
[114] 朱显谟.论原始土壤的成土过程[J].水土保持研究,1995,13(4):83-89.
[115] 李阳兵,王世杰,李瑞玲.岩溶生态系统的土壤[J].生态环境学报,2004,13(3):434-438.
[116] 王雪芹,张元明,张伟民,等.古尔班通古特沙漠生物结皮对地表风蚀作用影响的风洞试验[J].冰川冻土,2004,26(5):632-638.
[117] 肖波,赵允格,邵明安.黄土高原侵蚀区生物结皮的人工培育及其水土保持效应[J].草地学报,2008,16(1):28-33.
[118] Hu R, Wang X, Pan Y, et al. The response mechanisms of soil N mineralization under biological soil crusts to temperature and moisture in temperate desert regions[J]. European Journal of Soil Biology, 2014,62:66-73.
[119] 王家文,周跃,肖本秀,等.中国西南喀斯特土壤水分特征研究进展[J].中国水土保持,2013(2):37-41.
[120] 雷丽,程星,蔡雄飞.贵州岩溶山区土壤含水量时空分布与植物生长关系研究[J].贵州科学,2009,27(2):50-54.
[121] 邵明安.土壤物理学[M].北京:高等教育出版社,2006.
[122] 周小泉,刘政鸿,杨永胜,等.毛乌素沙地3种植被下苔藓结皮的土壤理化效应[J].水土保持研究,2014,21(6):340-344.
[123] Kidron G J. Analysis of dew precipitation in three habitats within a small arid drainage basin, Negev Highlands, Israel[J]. Atmospheric Research, 2000,55(3):257-270.
[124] Kidron G J, Aaron Y, Avinoam D. Dew variability within a small arid drainage basin in the Negev Highlands, Israel[J]. Quarterly Journal of the Royal Meteorological Society, 2010,126(562):63-80.
[125] Li X Y. Effects of gravel and sand mulches on dew deposition in the semiarid region of China[J]. Journal of Hydrology, 2002,260(1/4):151-160.
[126] Xiang C G, Pan G X, Zhang P J, et al. Horizon of Soil fauna diversity in karst soils in stone forest national park, Yunnan Province, China[J]. Acta Carsologica, 2003,32(2):187-194.
[127] 王振中,张友梅,邢协加.土壤环境变化对土壤动物群落影响的研究[J].土壤学报,2002,39(6):892-897.
[128] Li X R, Xiao H L, Zhang J G, et al. Long-term ecosystem effects of sand-binding vegetation in the tengger desert, Northern China[J]. Restoration Ecology, 2004,12(3):376-390.
[129] 陈孟晨,张景光,刘立超,等.生物土壤结皮对一年生植物影响研究进展[J].中国沙漠,2017,37(3):483-490.
[130] 张元明,聂华丽.生物土壤结皮对准噶尔盆地5种荒漠植物幼苗生长与元素吸收的影响[J].植物生态学报,2011,35(4):380-388.
[131] Wang S D, Bai X L, Yong S P. Preliminary research on bryoflora in Shapotou area[J]. Journal of Desert Research, 2001,21(3):244-249.
- Similar References:
Memo
-
Last Update:
2020-02-25