Cultivating Erect Milkvetch (Astragalus adsurgens Pall.) (Leguminosae) Improved Soil Properties in Loess Hilly and Gullies in China

doi:10.1016/S2095-3119(13)60394-0

Journal of Integrative Agriculture ›› 2013, Vol. 12 ›› Issue (9): 1652-1658.DOI: 10.1016/S2095-3119(13)60394-0

Cultivating Erect Milkvetch (Astragalus adsurgens Pall.) (Leguminosae) Improved Soil Properties in Loess Hilly and Gullies in China

WANG Zhan-bin , WANG Qing-yi

Animal Science and Technology School, Henan University of Science and Technology, Luoyang 471003, P.R.China

收稿日期:2012-10-15 出版日期:2013-09-01 发布日期:2013-09-15
通讯作者: Correspondence WANG Zhan-bin, Tel: +86-379-64283833, Fax: +86-379-64280348, E-mail: wangzhanbin3696@126.com
基金资助:
This study was supported by the Key Programs for Science and Technology Development of Henan Province of China (0724090017).

Cultivating Erect Milkvetch (Astragalus adsurgens Pall.) (Leguminosae) Improved Soil Properties in Loess Hilly and Gullies in China

WANG Zhan-bin , WANG Qing-yi

Animal Science and Technology School, Henan University of Science and Technology, Luoyang 471003, P.R.China

Received:2012-10-15 Online:2013-09-01 Published:2013-09-15
Contact: Correspondence WANG Zhan-bin, Tel: +86-379-64283833, Fax: +86-379-64280348, E-mail: wangzhanbin3696@126.com
Supported by:
This study was supported by the Key Programs for Science and Technology Development of Henan Province of China (0724090017).

摘要/Abstract

摘要： Erect milkvetch (Astragalus adsurgens Pall.), a leguminous grass, is a major source of fuel and forage, and has an important role in the restoration of the degraded ecosystems in central and northeastern China. The objective of this work was to investigate how erect milkvetch planting would affect the physical and chemical properties of soil in degraded arable lands. Soil samples at the depths of 0-20 and 20-40 cm were collected from erect milkvetch planting fileds at ages of 0, 1, 2 and 3 yr. Changes in soil bulk density, soil porosity, total N and P, organic matter content, available P, hydrolysable N and available K were measured. The results showed that root biomass and above-ground plant biomass were both significantly increased with plantation age. The significant increase in root nodule biomass was not observed in the first two years. However, it was significantly increased after three years. Root growth of erect milkvetch improved soil structure, and hence, decreased soil bulk density and increased soil porosity. Furthermore, the nitrogen fixation by erect milkvetch and return of erect milkvetch plant to soil increased the soil total N, hydrolysable N and organic matter content of the soil. Low concentrations of P in the soil with erect milkvetch planting could be ascribed to high plant uptakes and possibly to high sequestrations of P in plant biomass. Concentrations of K significantly increased during the first two years of erect milkvetch planting. The high accumulation of K under erect milkvetch cultivation in the first two years could partly be attributed to low plant uptake, and partly to relatively quick recycling within plant-soil systems. Three years after erect milkvetch plantingr, K accumulation at 0-20 cm soil layer was significantly lower than that from non-vegetated field sites, which could be attributed to high plant uptake. These parameters, except for soil bulk density, were all decreased with increasing soil depth. Soil total N, organic matter, porosity and available K in the 20-40 cm layer all showed linear increase trends, and soil bulk density, total P and available P in the depth 0-20 cm layer soil were decreased with increasing planting age. Erect milkvetch establishment could be an effective and applicable measure to improve soil nutrients, and prevent further soil degradation and erosion.

关键词: Asuagalus adsurgens Pall. , soil properties , plantation age , loess hills and gullies

Abstract: Erect milkvetch (Astragalus adsurgens Pall.), a leguminous grass, is a major source of fuel and forage, and has an important role in the restoration of the degraded ecosystems in central and northeastern China. The objective of this work was to investigate how erect milkvetch planting would affect the physical and chemical properties of soil in degraded arable lands. Soil samples at the depths of 0-20 and 20-40 cm were collected from erect milkvetch planting fileds at ages of 0, 1, 2 and 3 yr. Changes in soil bulk density, soil porosity, total N and P, organic matter content, available P, hydrolysable N and available K were measured. The results showed that root biomass and above-ground plant biomass were both significantly increased with plantation age. The significant increase in root nodule biomass was not observed in the first two years. However, it was significantly increased after three years. Root growth of erect milkvetch improved soil structure, and hence, decreased soil bulk density and increased soil porosity. Furthermore, the nitrogen fixation by erect milkvetch and return of erect milkvetch plant to soil increased the soil total N, hydrolysable N and organic matter content of the soil. Low concentrations of P in the soil with erect milkvetch planting could be ascribed to high plant uptakes and possibly to high sequestrations of P in plant biomass. Concentrations of K significantly increased during the first two years of erect milkvetch planting. The high accumulation of K under erect milkvetch cultivation in the first two years could partly be attributed to low plant uptake, and partly to relatively quick recycling within plant-soil systems. Three years after erect milkvetch plantingr, K accumulation at 0-20 cm soil layer was significantly lower than that from non-vegetated field sites, which could be attributed to high plant uptake. These parameters, except for soil bulk density, were all decreased with increasing soil depth. Soil total N, organic matter, porosity and available K in the 20-40 cm layer all showed linear increase trends, and soil bulk density, total P and available P in the depth 0-20 cm layer soil were decreased with increasing planting age. Erect milkvetch establishment could be an effective and applicable measure to improve soil nutrients, and prevent further soil degradation and erosion.

Key words: Asuagalus adsurgens Pall. , soil properties , plantation age , loess hills and gullies

WANG Zhan-bin , WANG Qing-yi. Cultivating Erect Milkvetch (Astragalus adsurgens Pall.) (Leguminosae) Improved Soil Properties in Loess Hilly and Gullies in China[J]. Journal of Integrative Agriculture, 2013, 12(9): 1652-1658.

参考文献

[1]Cao C Y, Jiang D M, Alamsa, Luo Y M, Kou Z W. 2000.Ecological processes of vegetation restoration ofCaragana microphylla in the sand fixing area. ChinaJournal of Applied Ecology, 11, 349-354 (in Chinese)

[2]Cao C Y, Jiang D M, Luo Y M, Kou Z W. 2004. Stability ofCaragana microphylla plantation for wind protectionand sand fixation. Acta Ecologica Sinica, 24, 1178-1185 (in Chinese)

[3]Carlsson1 G, Huss-Danell K. 2003. Nitrogen fixation inperennial forage legumes in the field. Plant and Soil,253, 353-372

[4]Ehrenfeld J G. 2001. Plant-soil interactions. In: Levin S, ed.,Encyclopedia of Biodiversity. Academic Press, SanDiego, CA. pp. 689-709

[5]Ehrenfeld J G. 2003. Effects of exotic plant invasions onsoil nutrient cycling processes. Ecosystems, 6, 503-523

[6]El Tahir B A, Ahmed D M, Ardo J, Gaafar A M, Salih A A.2009. Changes in soil properties following conversionof Acacia senegal plantation to other land managementsystems in North Kordofan State, Sudan. Journal ofArid Environments, 73, 499-505

[7]Emteryd O. 1989. Chemical and Physical Analysis ofInorganic Nutrients in Plant, Soil, Water and Air.Stencil No. 10. Swedish University of AgriculturalSciences, Uppsala, Sweden.Grierson P F, Adams M A. 2000. Plant species affect acidphosphatase, ergosterol and microbial P in a Jarrah(Eucalyptus marginata Donn ex Sm.) forest insouthwestern Australia. Soil Biology and Biochemistry,32, 1817-27

[8]Guo Y Q. 2007. Environmental characteristics of soil erosionand erosion category division of the Yellow River basinin west Henan. Soil and Water Conservation in China,7, 22-24 (in Chinese)

[9]Guo Z S, Shao M A. 2003. Soil water carrying capacity ofvegetation and soil desiccation in artificial forestry andgrassland in semi-arid regions of the Loess Plateau.Acta Ecologica Sinica, 23, 1640-1647 (in Chinese)

[10]Hallett P D, Young I M. 1999. Changes to water repellenceof soil aggregates caused by substrate-induced microbial activity. European Journal of Soil Science,50, 35-40

[11]Harris W N, Moretto A S, Distel R A, Boutton T W, Boo RM. 2007. Fire and grazing in grasslands of the ArgentineCaldenal: effects on plant and soil carbon and nitrogen.Acta Oecologica, 32, 207-214

[12]Institute of Soil Sciences, Chinese Academy of Sciences.1978. Physical and Chemical Analysis Methods of Soils.Shanghai Science and Technology Press, Shanghai. p.283. (in Chinese)Institute of Soil Sciences, Chinese Academy of Sciences.1983. Physical and Chemical Analysis Methods of Soils.Shanghai Science and Technology Press, Shanghai. (inChinese)Kourtev P S, Ehrenfeld J G, H鋑gblom M. 2002. Exotic plantspecies alter the microbial community structure andfunction in the soil. Ecology, 83, 3152-3166

[13]Liu P S, Jia Z K, Li J, Wang J P, Li Y P, Liu S X. 2009.Moisture distribution characteristics and the time-spacedynamics of the soil dry layer in alfalfa farmlands inarid region s of southern Ningxia. Journal of NaturalResources, 24, 663-673 (in Chinese)

[14]Liu Z J, Li B P, Li Y H, Cui Y L. 2004. Theory and techniquesof restoring and reconstructing vegetation in loess hillyarea in Yuxi. Journal of Mountain Science, 22, 393-399 (in Chinese)

[15]Mulvaney R L. 2001. Diffusion methods to determinedifferent forms of nitrogen in soil hydrolysates. SoilScience Society of America Journal, 65, 1284-1292

[16]Nelson D W, Sommers L E. 1975. A rapid and accuratemethod for estimating organic carbon in soil.Proceedings of the Indiana Academy of Science, 84,456-462

[17]Parkinson J A, Allen S E. 1975. A wet oxidation proceduresuitable for determination of nitrogen and mineralnutrients in biological material. Communications inSoil Science and Plant Analysis, 6, 1-11

[18]Pei W G. 2009. Research on vegetation model ofrehabilitation and reconstruction in the loess hilly andgully region in western Henan-Taking the loess hillyand gully area in Sanmenxia suburbs as an example.Central South Forest Inventory And Planning, 28, 16-18, 39

[19]Ren J J, Li J, Wang X C, Fang X Y. 2011. Soil water andnutrient characteristics of alfalfa grasslands at semiaridand semi-arid prone to drought areas in southernNingxia. Acta Ecologica Sinica, 31, 3638-3649 (in Chinese)

[20]Shang Z H, Ma Y S, Long R J, Ding L M. 2008. Effect offencing, artificial seeding and abandonment onvegetation composition and dynamics of 慴lack soilland?in the headwaters of the Yangtze and the YellowRivers of the Qinghai-Tibetan plateau. LandDegradation & Development, 19, 554-563

[21]Singh J S, Jha A K. 1993. Restoration of degraded land: anoverview. In: Singh J S, ed., Restoration of DegradedLand: Concepts and Strategies. Restogi Publications,Meerut. pp. 1-9

[22]Su Y Z, Zhao H L, Zhang T H, Zhao X Y. 2004. Soil propertiesfollowing cultivation and non-grazing of a semi-aridsandy grassland in northern China. Soil and TillageResearch, 75, 27-36

[23]Wang Y, Guo Y. 1993. Establishment of artificial grasslandson the degraded Stipa steppe in the Alihe Area, highlatitude zone of China. Journal of Japanese Society ofGrassland Science, 39, 343-348

[24]Wang Y Q, Shao M A, Shao H B. 2010. A preliminaryinvestigation of the dynamic characteristics of driedsoil layers on the Loess Plateau of China. Journal ofHydrology, 381, 9-17

[25]Wu G L, Liu Z H, Zhang L, Hu T M, Chen J M. 2010. Effectsof artificial-grassland establishment on plant communityand soil properties in a black-soil-type degradedgrassland. Plant and Soil, 333, 469-479

[26]Yang H S, Cao M J, Fan F, Zhang Q G, Sun D Z. 2006.Effects of the number of growth years of alfalfa on thephysical and chemical properties of soil. ChineseJournal of Grassland, 28, 29-32 (in Chinese)

[27]Zhu L Q. 2001. Study on soil erosion and its affects onagriculture sustainable development in west Henanprovince loess hilly and mountainous areas. Journalof Soil and Water Conservation, 15, 41-45, 55 (in Chinese)

Cultivating Erect Milkvetch (Astragalus adsurgens Pall.) (Leguminosae) Improved Soil Properties in Loess Hilly and Gullies in China

Cultivating Erect Milkvetch (Astragalus adsurgens Pall.) (Leguminosae) Improved Soil Properties in Loess Hilly and Gullies in China

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 0

编辑推荐

Metrics