严重沙化草地治理效果分析

doi:10.12160/j.issn.1672-5190.2021.05.010

畜牧与饲料科学 ›› 2021, Vol. 42 ›› Issue (5): 55-60.doi: 10.12160/j.issn.1672-5190.2021.05.010

严重沙化草地治理效果分析

乌日拉嘎¹, 刘慧洁¹, 萨如拉¹, 郝巴雅斯胡良², 乌亚罕², 特木尔布和¹

1.内蒙古农业大学草原与资源环境学院,内蒙古呼和浩特 010019;
2.鄂尔多斯市鄂托克前旗现代农牧业新技术推广办公室,内蒙古鄂托克前旗 016100

收稿日期:2021-07-08 出版日期:2021-09-30 发布日期:2021-11-25
通讯作者: 特木尔布和（1963—）,男,副教授,博士,硕士生导师,主要从事牧草栽培育种教学和科研工作。
作者简介:乌日拉嘎（1998—）,女,硕士研究生,主要研究方向为牧草种质资源与育种。
基金资助:
农业农村部公益性行业（农业）科研专项项目（201303059）

Effects of Improvement Strategy on Severely Desertified Grassland

Wurilaga¹, LIU Hui-jie¹, Sarula¹, Haobayasihuliang², Wuyahan², Temuerbuhe¹

1. College of Grassland,Resources and Environment,Inner Mongolia Agricultural University,Hohhot 010019,China;
2. New Technology Extension Office of Modern Agriculture and Animal Husbandry of Otog Front Banner of Ordos City,Otog Front Banner 016100,China

Received:2021-07-08 Online:2021-09-30 Published:2021-11-25

摘要/Abstract

摘要： [目的] 探究严重沙化草地治理效果,为草地治理、开发和合理利用提供参考。[方法] 2015—2017年,在严重沙化治理区采用同行条播方式混播紫花苜蓿（Medicago sativa）、沙打旺（Astragalus adsurgens）、草木樨（Melilotus officinalis）、羊柴（Hedysarum laeve）、披碱草（Elymus dahuricus）和老芒麦（Elymus sibiricus）6种优良牧草。以自由放牧区为对照,采用棋盘式取样法进行植物种类调查;测定植物多度、频度、盖度、高度和产量;对植物CO₂吸收率、光合速率、蒸腾速率、气孔导度进行测定,并进行多元相关分析;计算植物Shannon-Wiener多样性指数,测定土壤养分含量及电导率。[结果] 严重沙化草地治理后植物种类由治理前（2015年）的14种,分别上升到2018年、2019年和2020年的72、83和97种;与自由放牧区相比,严重沙化治理区牧草的平均高度、盖度、多度、频度及产量均显著（P<0.05）提高;严重沙化治理区的CO₂吸收率、光合速率、蒸腾速率及气孔导度均显著（P<0.05）高于自由放牧区,蒸腾速率与光合速率（P<0.05）、气孔导度与蒸腾速率（P<0.05）、牧草产量与光合速率（P<0.05）和蒸腾速率（P<0.01）具有显著或极显著正相关关系;严重沙化治理区和自由放牧区的主要牧草Shannon-Wiener多样性指数具有显著（P<0.05）差异;严重沙化治理区土壤的有机质、速效磷、速效钾含量以及土壤电导率显著（P<0.05）高于自由放牧区。[结论] 严重沙化草地经过治理植物种类数量剧增,牧草生产水平和草地生态效益大幅度提升,土壤养分显著改善。

关键词: 严重沙化草地, 自由放牧, 牧草混播, 治理效果

Abstract: [Objective] To ascertain the effects of improvement strategy on severely desertified grassland, and to provide references for management, development and rational use of grassland. [Method] From the year of 2015 to 2017, mixed seeding of 6 varieties of high-quality forages sowed with drilling method, including Medicago sativa, Astragalus adsurgens, Melilotus officinalis, Hedysarum laeve, Elymus dahuricus and Elymus sibiricus, were set in a severely desertified grassland area. Using free-grazing area as control, the plant species were investigated by chessboard-sampling method; the abundance, frequency, coverage, height and yield of the plants were determined; the CO₂ absorption rate, photosynthetic rate, transpiration rate and stomatal conductance of the plants were assessed and subjected to multivariate correlation analysis. Furthermore, the Shannon-Wiener diversity index of the plants was calculated, and the soil nutrient contents and electrical conductivity were determined. [Result] The number of plant species in severely desertified grassland increased from 14 before improvement （in the year of 2015） to 72, 83 and 97 in the years of 2018, 2019 and 2020 after improvement, respectively; compared with free-grazing area, the average abundance, frequency, coverage, height and yield of the forages in the improvement area were significantly （P<0.05） increased; this area had significantly （P<0.05） higher CO₂ absorption rate, photosynthetic rate, transpiration rate and stomatal conductance in comparison with free-grazing area, and there were significantly or extremely significantly positively correlations between transpiration rate and photosynthetic rate （P<0.05）, stomatal conductance and transpiration rate （P<0.05）, forage yield and photosynthetic rate （P<0.05）, as well as forage yield and transpiration rate （P<0.01）; significant （P<0.05） differences in Shannon-Wiener diversity index of the main forage species between improvement area and free-grazing area were observed; the soil contents of organic matter, available phosphorus and available potassium as well as soil electrical conductivity in improvement area were significantly （P<0.05） higher than those in free-grazing area. [Conclusion] After improvement, the severely desertified grassland has dramatically increased number of plant species, greatly improved forage production level and grassland ecological benefit, and significantly ameliorated soil nutrients.

Key words: severely desertified grassland, free grazing, mixed seeding of forages, improvement effect

中图分类号:

S812.68

乌日拉嘎, 刘慧洁, 萨如拉, 郝巴雅斯胡良, 乌亚罕, 特木尔布和. 严重沙化草地治理效果分析[J]. 畜牧与饲料科学, 2021, 42(5): 55-60.

Wurilaga, LIU Hui-jie, Sarula, Haobayasihuliang, Wuyahan, Temuerbuhe. Effects of Improvement Strategy on Severely Desertified Grassland[J]. Animal Husbandry and Feed Science, 2021, 42(5): 55-60.

参考文献

[1] 赵爽,高福元,贾佳,等.毛乌素沙地风沙沉积物磁学特征及其古环境意义[J].地球物理学报,2015,58(10):3706-3718.
[2] 刘媖心. 试论我国沙漠地区植物区系的发生与形成[J].植物分类学报,1995(2):131-143.
[3] 董雯,赵景波.毛乌素沙地的形成与治理[J].贵州师范大学学报(自然科学版),2006,24(4):42-46.
[4] 王岳,刘学敏,哈斯额尔敦.毛乌素沙地“沙产业”发展水平评价[J].中国软科学,2019(6):22-34.
[5] 刘毅,赵贝佳.毛乌素沙地是这样变绿的[EB/OL]. (2020-12-21).https://wap.peopleapp.com/article/6055170/5968066.
[6] 李德新,卫智军,韩国栋,等.中国荒漠草原生态系统研究[M].北京:科学出版社,2013.
[7] 杨持. 生态学[M].北京:高等教育出版社,2014.
[8] 山蓝,杨晓东,高卫东,等.关于内蒙古草地生态建设问题的思考[J].中国草地,1998(6):63-65,73.
[9] 焦婷,赵生国,祁娟,等.放牧强度对温性荒漠草原土壤全氮和有机质的影响[J].草原与草坪,2012,32(5):22-25.
[10] 段淳清. 内蒙古草地资源现状及其可持续利用对策[J].内蒙古草业,2006(3):21-25.
[11] 曹艳萍,庞营军,贾晓红.2001—2016年毛乌素沙地植被的生长状况[J].水土保持通报,2019,39(2):29-37.
[12] 张军,刘菊红,王忠武,等.内蒙古荒漠草原植物群落特征对放牧利用和降水条件的响应[J].中国草地学报,2020,42(6):67-74.
[13] 税伟,白剑平,简小枚,等.若尔盖沙化草地恢复过程中土壤特性及水源涵养功能[J].生态学报,2017,37(1):277-285.
[14] 赵晓军. 退化草地治理方式及改良效果研究进展[J].今日畜牧兽医,2020,36(4):66.
[15] 任国玉. 全球气候变化研究现状与方向[C]//大气科学发展战略——中国气象学会第25次全国会员代表大会暨学术年会论文集.北京:中国气象学会,2002:6.
[16] 侯扶江. 放牧对牧草光合作用、呼吸作用和氮、碳吸收与转运的影响[J].应用生态学报,2001(6):938-942.
[17] PARSONS T A,王昱生,杨殿臣.放牧下牧草的生产生理——Ⅱ连续放牧草地的光合作用、牧草生长和家畜采食[J].自然资源研究,1985(S1):107-117.
[18] 刘翠玲. 草地生态系统服务功能的研究与开发[J].中国农村小康科技,2010(10):77-79.
[19] 孙海燕,万书波,李林,等.放牧对荒漠草原土壤养分及微生物量的影响[J].水土保持通报,2015,35(2):82-88,93.
[20] 李淑敏,李红,周连第.土壤电导率的快速测量(EM38)与数据的研究应用[J].安徽农业科学,2009,37(29):14001-14004,14015.

严重沙化草地治理效果分析

Effects of Improvement Strategy on Severely Desertified Grassland

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