Effects of <i>Caragana microphylla </i>plantations on organic carbon sequestration in total and labile soil organic carbon fractions in the Horqin Sandy Land, northern China

doi:10.1007/s40333-017-0063-x

Journal of Arid Land

2017, Vol. 9

Issue (5): 688-700 DOI: 10.1007/s40333-017-0063-x

Orginal Article

Effects of Caragana microphylla plantations on organic carbon sequestration in total and labile soil organic carbon fractions in the Horqin Sandy Land, northern China

Wen SHANG^1,², Yuqiang LI^2,^*(

), Xueyong ZHAO², Tonghui ZHANG², Quanlin MA¹, Jinnian TANG¹, Jing FENG², Na SU²

¹State Key Laboratory Breeding Base of Desertification and Aeolian Sand Disaster Combating, Gansu Desert Control Research Institute, Lanzhou 730070, China
²Naiman Desertification Research Station, Northwest Institute of Eco-Environment and Resources, Chinese Academy of Sciences, Lanzhou 730000, China

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Abstract

Afforestation is conducive to soil carbon (C) sequestration in semi-arid regions. However, little is known about the effects of afforestation on sequestrations of total and labile soil organic carbon (SOC) fractions in semi-arid sandy lands. In the present study, we examined the effects of Caragana microphylla Lam. plantations with different ages (12- and 25-year-old) on sequestrations of total SOC as well as labile SOC fractions such as light fraction organic carbon (LFOC) and microbial biomass carbon (MBC). The analyzed samples were taken from soil depths of 0-5 and 5-15 cm under two shrub-related scenarios: under shrubs and between shrubs with moving sand dunes as control sites in the Horqin Sandy Land of northern China. The results showed that the concentrations and storages of total SOC at soil depths of 0-5 and 5-15 cm were higher in 12- and 25-year-old C. microphylla plantations than in moving sand dunes (i.e., control sites), with the highest value observed under shrubs in 25-year-old C. microphylla plantations. Furthermore, the concentrations and storages of LFOC and MBC showed similar patterns with those of total SOC at the same soil depth. The 12-year-old C. microphylla plantations had higher percentages of LFOC concentration to SOC concentration and MBC concentration to SOC concentration than the 25-year-old C. microphylla plantations and moving sand dunes at both soil depths. A significant positive correlation existed among SOC, LFOC, and MBC, implying that restoring the total and labile SOC fractions is possible by afforestation with C. microphylla shrubs in the Horqin Sandy Land. At soil depth of 0-15 cm, the accumulation rate of total SOC under shrubs was higher in young C. microphylla plantations (18.53 g C/(m²?a); 0-12 years) than in old C. microphylla plantations (16.24 g C/(m²?a); 12-25 years), and the accumulation rates of LFOC and MBC under shrubs and between shrubs were also higher in young C. microphylla plantations than in old C. microphylla plantations. It can be concluded that the establishment of C. microphylla in the Horqin Sandy Land may be a good mitigation strategy for SOC sequestration in the surface soils.

Key words： Caragana microphylla plantation soil organic carbon light fraction organic carbon microbial biomass carbon carbon accumulation rate Horqin Sandy Land

Received: 13 January 2017 Published: 22 August 2017

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	Wen SHANG
	Yuqiang LI
	Xueyong ZHAO
	Tonghui ZHANG
	Quanlin MA
	Jinnian TANG
	Jing FENG
	Na SU

Cite this article:

Wen SHANG, Yuqiang LI, Xueyong ZHAO, Tonghui ZHANG, Quanlin MA, Jinnian TANG, Jing FENG, Na SU. Effects of Caragana microphylla plantations on organic carbon sequestration in total and labile soil organic carbon fractions in the Horqin Sandy Land, northern China. Journal of Arid Land, 2017, 9(5): 688-700.

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http://jal.xjegi.com/10.1007/s40333-017-0063-x OR http://jal.xjegi.com/Y2017/V9/I5/688

[1]	Anderson T H, Domsch K H.1989. Ratios of microbial biomass carbon to total organic carbon in arable soils. Soil Biology & Biochemistry, 21(4): 471-479.
[2]	Arai H, Tokuchi N.2010. Factors contributing to greater soil organic carbon accumulation after afforestation in a Japanese coniferous plantation as determined by stable and radioactive isotopes. Geoderma, 157(3-4): 243-251.
[3]	Bárcena T G, Gundersen P, Vesterdal L.2014. Afforestation effects on SOC in former cropland: oak and spruce chronosequences resampled after 13 years. Global Change Biology, 20(9): 2938-2952.
[4]	Berthrong S T, Pi?eiro G, Jobbágy E G, et al.2012. Soil C and N changes with afforestation of grasslands across gradients of precipitation and plantation age. Ecological Application, 22(1): 76-86.
[5]	Bhojvaid P P, Timmer V R.1998. Soil dynamics in an age sequence of Prosopis juliflora planted for sodic soil restoration in India. Forest Ecology and Management, 106(2-3): 181-193.
[6]	Bradshaw A D.1983. The reconstruction of ecosystems: Presidential address to the British ecological society, December 1982. Journal of Applied Ecology, 20(1): 1-17.
[7]	Cao C Y, Jiang D M, Teng X H, et al.2008. Soil chemical and microbiological properties along a chronosequence of Caragana microphylla Lam. plantations in the Horqin Sandy Land of Northeast China. Applied Soil Ecology, 40(1): 78-85.
[8]	Del Galdo I, Six J, Peressotti A, et al.2003. Assessing the impact of land-use change on soil C sequestration in agricultural soils by means of organic matter fractionation and stable C isotopes. Global Change Biology, 9(8): 1204-1213.
[9]	Deng L, Wang K B, Shangguan Z P.2014. Long-term natural succession improves nitrogen storage capacity of soil on the Loess Plateau, China. Soil Research, 52(3): 262-270.
[10]	Deng L, Shangguan Z P.2016. Afforestation drives soil carbon and nitrogen changes in China. Land Degradation & Development, 28(1): 151-165.
[11]	Duan Z H, Xiao H L, Dong Z B, et al.2007. Morphological, physical and chemical properties of aeolian sandy soils in northern China. Journal of Arid Environments, 68(1): 66-76.
[12]	Giardina C P, Binkley D, Ryan M G, et al.2004. Belowground carbon cycling in a humid tropical forest decreases with fertilization. Oecologia, 139(4): 545-550.
[13]	Gregorich E G, Beare M H, McKim U F, et al.2006. Chemical and biological characteristics of physically uncomplexed organic matter. Soil Science Society of America Journal, 70(3): 975-985.
[14]	Han X H, Zhao F Z, Tong X G, et al.2017. Understanding soil carbon sequestration following the afforestation of former arable land by physical fractionation. Catena, 150: 317-327.
[15]	Higginbottom T P, Symeonakis E.2014. Assessing land degradation and desertification using vegetation index data: current frameworks and future directions. Remote Sensing, 6(10): 9552-9575.
[16]	Hu Y L, Zeng D H, Fan Z P, et al.2008. Changes in ecosystem carbon stocks following grassland afforestation of semiarid sandy soil in the southeastern Keerqin Sandy Lands, China. Journal of Arid Environment, 72(12): 2193-2200.
[17]	Huang W D, Zhao X Y, Zhao X, et al.2016. Effects of environmental factors on genetic diversity of Caragana microphylla in Horqin Sandy Land, northeast China. Ecology and Evolution, 6(22): 8256-8266.
[18]	ISO (International Organization for Standardization). 1998. ISO 11277: soil quality-determination of particle size distribution in mineral soil material-method by sieving and sedimentation. Geneva, Switzerland: ISO.
[19]	Janzen H H, Campbell C A, Brandt S A, et al.1992. Light fraction organic matter in soils from long-term crop rotations. Soil Science Society of America Journal, 56(6): 1799-1806.
[20]	Jenkinson D S.1988. The determination of microbial biomass carbon and nitrogen in soil. In Wilson J R. Advances in Nitrogen Cycling in Agricultural Ecosystems. Wallingford, UK: CAB International, 368-386.
[21]	Jobbágy E G, Jackson R B.2000. The vertical distribution of soil organic carbon and its relation to climate and vegetation. Ecological Application, 10(2): 423-436.
[22]	Lai Z R, Liu J B, Zhang Y Q, et al.2017. Introducing a shrub species in a degraded steppe shifts fine root dynamics and soil organic carbon accumulations, in northwest China. Ecological Engineering, 100: 277-285.
[23]	Laganière J, Angers D A, Pare D.2010. Carbon accumulation in agricultural soils after afforestation: a meta-analysis. Global Change Biology, 16(1): 439-453.
[24]	Laik R, Kumar K, Das D K, et al.2009. Labile soil organic matter pools in a calciorthent after 18 years of afforestation by different plantations. Applied Soil Ecology, 42(2): 71-78.
[25]	Lal R.2001. Potential of desertification control to sequester carbon and mitigate the greenhouse effect. Climatic Change, 51(1): 35-72.
[26]	Lal R. 2014. Desertification and soil erosion. In: Freedman B. Global Environmental Change. Netherlands: Springer, 369-378.
[27]	Li Y L, Chen J, Cui J Y, et al.2012. Nutrient resorption in Caragana microphylla along a chronosequence of plantations: implications for desertified land restoration in North China. Ecological Engineering, 53: 299-305.
[28]	Li Y Q, Awada T, Zhou X H, et al.2012. Mongolian pine plantations enhance soil physico-chemical properties and carbon and nitrogen capacities in semi-arid degraded sandy land in China. Applied Soil Ecology, 56: 1-9.
[29]	Liu S J, Zhang W, Wang K L, et al.2015. Factors controlling accumulation of soil organic carbon along vegetation succession in a typical Karst region in southwest China. Science of the Total Environment, 521-522: 52-58.
[30]	Nadal-Romero E, Cammeraat E, Serrano-Muela M P, et al.2016. Hydrological response of an afforested catchment in a Mediterranean humid mountain area: A comparative study with a natural forest. Hydrological Processes, 30(15): 2717-2733.
[31]	Paul K I, Polglase P J, Nyakuengama J G, et al.2002. Change in soil carbon following afforestation. Forest Ecology and Management, 168(1-3): 241-257.
[32]	Post W M, Kwon K C.2000. Soil carbon sequestration and land-use change: processes and potential. Global Change Biology, 6(3): 317-327.
[33]	Rytter R-M.2016. Afforestation of former agricultural land with Salicaceae species-initial effects on soil organic carbon, mineral nutrients, C:N and pH. Forest Ecology and Management, 363: 21-30.
[34]	Schimel D S, Braswell B H, Holland E A, et al.1994. Climatic, edaphic, and biotic controls over storage and turnover of carbon in soils. Global Biogeochemical Cycles, 8(3): 279-293.
[35]	Shi S W, Han P F, Zhang P, et al.2015. The impact of afforestation on soil organic carbon sequestration on the Qinghai Plateau, China. PLoS ONE, 10(2): e0116591.
[36]	Su Y Z, Zhao H L.2003. Soil properties and plant species in an age sequence of Caragana microphylla plantations in the Horqin Sandy Land, north China. Ecological Engineering, 20(3): 223-235.
[37]	Tang G Y, Li K.2013. Tree species controls on soil carbon sequestration and carbon stability following 20 years of afforestation in a valley-type savanna. Forest Ecology and Management, 291: 13-19.
[38]	Teng X H, Cao C Y, Fu Y, et al.2007. Changes of soil enzyme activities and microbial biomass in an age sequence of Caragana microphylla plantation for sand-fixation. Ecological Environment, 16(3): 1030-1034. (in Chinese)
[39]	Torn M S, Trumbore S E, Chadwick O A, et al.1997. Mineral control of soil organic carbon storage and turnover. Nature, 389(6647): 170-173.
[40]	UNCCD.1994. United Nations Convention to combat Desertification in those countries experiencing serious drought and/or desertification, particularly in Africa. Geneva: UNEP.
[41]	Vance E D, Brookes P C, Jenkinson D S.1987. An extraction method for measuring soil microbial biomass C. Soil Biology and Biochemistry, 19(6): 703-707.
[42]	Vesterda L, Rosenqvist L, Van Der Salm C, et al. 2007. Carbon sequestration in soil and biomass following afforestation: experiences from oak and Norway spruce chronosequences in Denmark, Sweden and the Netherlands. In: Heil G W, Muys B, Hansen K. Environmental Effects of Afforestation in North-Western Europe. Netherlands: Springer, 1: 19-51.
[43]	Wang H M, Wang W J, Chen H F, et al.2014. Temporal changes of soil physic-chemical properties at different soil depths during larch afforestation by multivariate analysis of covariance. Ecology and Evolution, 4(7): 1039-1048.
[44]	Wang K B, Deng L, Ren Z P, et al.2016. Dynamics of ecosystem carbon stocks during vegetation restoration on the Loess Plateau of China. Journal of Arid Land, 8(2): 207-220.
[45]	Wang S K, Zhao X Y, Zhang T H, et al.2013. Afforestation effects on soil microbial abundance, microbial biomass carbon and enzyme activity in dunes of Horqin Sandy Land, northeastern China. Sciences in Cold and Arid Regions, 5(2): 184-190.
[46]	Wissing L, Kolbl A, Vogelsang V, et al.2011. Organic carbon accumulation in a 2000-year chronosequence of paddy soil evolution. Catena, 87(3): 376-385.
[47]	Xie J S, Guo J F, Yang Z J, et al.2013. Rapid accumulation of carbon on severely eroded red soils through afforestation in subtropical China. Forest Ecology and Management, 300: 53-59.
[48]	Yang T, Xu H, Li H, et al.2005. Soil nutrient, microorganism and enzyme activity in Pinuse sylvestris plantations. Journal of Soil and Water Conservation, 19(3): 50-53. (in Chinese)
[49]	Yue G Y, Zhao H L, Zhang T H, et al.2008. Evaluation of water use of Caragana microphylla with the stem heat-balance method in Horqin Sandy Land, Inner Mongolia, China. Agricultural and Forest Meteorology, 148(11): 1668-1678.
[50]	Zhang T H, Su Y Z, Cui J Y, et al.2006. A leguminous shrub (Caragana microphylla) in semiarid sandy soils of North China. Pedosphere, 16(3): 319-325.
[51]	Zhao H L, Zhou R L, Su Y Z, et al.2007. Shrub facilitation of desert land restoration in the Horqin Sand Land of Inner Mongolia. Ecological Engineering, 31(1): 1-8.

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