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Journal of Arid Land  2017, Vol. 9 Issue (5): 678-687    DOI: 10.1007/s40333-017-0026-2
Orginal Article     
Long-term agricultural activity affects anthropogenic soil on the Chinese Loess Plateau
Xiaoyun LI1,2,*(), Yiquan WANG3, E REYNOLDS Mark4, Xiaoping LI1,2, Xinwei LU1
1 School of Geography and Tourism, Shaanxi Normal University, Xi’an 710119, China
2 SNNU-JSU Joint Research Center for Nano-environment Science and Health, Xi’an 710119, China
3 College of Resources and Environment, Northwest A&F University, Yangling 712100, China
4 Stockbridge School of Agriculture, University of Massachusetts, Massachusetts 01003, USA
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Anthropogenic activities largely influence the soil quality of agricultural fields and the composition of soil. Samples of typical anthropogenic Loutu soil in the Guanzhong area of the Loess Plateau, Shaanxi Province, China were collected and measured for soil compaction, bulk density, total organic carbon (TOC), active organic carbon (AOC), and soil enzyme activities to investigate spatial variations in soil quality. The results indicate that soil compaction and bulk density increased with increasing distance from the farm village, whereas soil TOC, AOC, and soil enzyme activities firstly increased and subsequently decreased with increasing distance from the farm village. All of the tested parameters presented clear concentric distribution. Vertically, soil compaction and bulk density in the topsoil were lower than those in the subsoil, but all other tested parameters in the topsoil were significantly higher than those in the subsoil. In addition, there was a significant positive correlation between organic carbon content and enzyme activities, confirming that the spatial distribution of Loutu soil characteristics has been affected by long-term anthropogenic activities to some extent. The results of this study imply that the use of farmyard manure and appropriate deep plowing are important and effective ways to maintain and improve soil quality.

Key wordsanthropogenic soil      spatial variation      organic carbon      enzyme activity      soil quality     
Received: 21 September 2016      Published: 22 August 2017
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Cite this article:

Xiaoyun LI, Yiquan WANG, E REYNOLDS Mark, Xiaoping LI, Xinwei LU. Long-term agricultural activity affects anthropogenic soil on the Chinese Loess Plateau. Journal of Arid Land, 2017, 9(5): 678-687.

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[1] Al-Hamaiedeh H, Bino M.2010. Effect of treated grey water reuse in irrigation on soil and plants. Desalination, 256(1-3): 115-119.
[2] Batey T.2009. Soil compaction and soil management-a review. Soil Use and Management, 25(4): 335-345.
[3] Berg B, Laskowski R.2005. Anthropogenic impacts on litter decomposition and soil organic matter. Advances in Ecological Research, 38: 263-290.
[4] Bergstrom D W, Monreal A D, Tomlin C M, et al.2000. Interpretation of soil enzyme activities in a comparison of tillage practices along a topographic and textural gradient. Canadian Journal of Soil Science, 80(1): 71-79.
[5] Berisso F E, Schj?nning P, Keller T, et al.2012. Persistent effects of subsoil compaction on pore size distribution and gas transport in a loamy soil. Soil and Tillage Research, 122: 42-51.
[6] Berzsenyi Z, Gy?rffy B, Lap D Q.2000. Effect of crop rotation and fertilisation on maize and wheat yields and yield stability in a long-term experiment. European Journal of Agronomy, 13(2-3): 225-244.
[7] Bhattacharyya R, Chandra S, Singh R D, et al.2007. Long-term farmyard manure application effects on properties of a silty clay loam soil under irrigated wheat-soybean rotation. Soil and Tillage Research, 94(2): 386-396.
[8] Blair B J, Lefroy R D B.1995. Soil carbon fractions based on their degree of oxidation, and the development of a carbon management index for agricultural systems. Australian Journal of Soil Research, 46(7): 1456-1466.
[9] Burges A, Epelde L, Garbisu C.2015. Impact of repeated single-metal and multi-metal pollution events on soil quality. Chemosphere, 120: 8-15.
[10] Calderón J F, Jackson L E, Scow K M, et al.2000. Microbial responses to simulated tillage in cultivated and uncultivated soils. Soil Biology and Biochemistry, 32(11-12): 1547-1559.
[11] Chamen W C T, Moxey A P, Towers W, et al.2015. Mitigating arable soil compaction: A review and analysis of available cost and benefit data. Soil and Tillage Research, 146: 10-25.
[12] Chang E H, Chung R S, Tsai Y H.2007. Effect of different application rates of organic fertilizer on soil enzyme activity and microbial population. Soil Science and Plant Nutrition, 53(2): 132-140.
[13] Colombo C, Palumbo G, Sannino F, et al. 2002. Chemical and biochemical indicators of managed agricultural soils. In: 17th World Congress of Soil Science. Bangkok, Thailand: WCSS, 1740-1-1740-9.
[14] Drijber R A, Doran J W, Parkhurst A M, et al.2000. Changes in soil microbial community structure with tillage under long-term wheat-fallow management. Soil Biology and Biochemistry, 32(10): 1419-1430.
[15] Dudal R, Nachtergaele F O, Purnell M F. 2002. The human factor of soil formation. In: Transactions 17th World Congress of Soil Science. Bangkok, Thailand: WCSS, 14-21.
[16] Etana A, Larsbo M, Keller T, et al.2013. Persistent subsoil compaction and its effects on preferential flow patterns in a loamy till soil. Geoderma, 192: 430-436.
[17] Franco I, Contin M, Bragato G, et al.2004. Microbiological resilience of soils contaminated with crude oil. Geoderma, 121(1-2): 17-30.
[18] Fu B J, Wang Y F, Lu Y H, et al.2009. The effects of land-use combinations on soil erosion: a case study in the Loess Plateau of China. Progress in Physical Geography, 33(6): 793-804.
[19] García-Gil J C, Plaza P S, Soler-Rovira P, et al.2000. Long-term effects of municipal solid waste compost application on soil enzyme activities and microbial biomass. Soil Biology and Biochemistry, 32(13): 1907-1913.
[20] Gary WW, Patrick K.2006. The impact of soil compaction on soil aeration and fine root density of Quercus palustris. Urban Forestry & Urban Greening, 4(2): 69-74.
[21] Gianfreda L, Rao A M, Piotrowska A, et al.2005. Soil enzyme activities as affected by anthropogenic alterations: intensive agricultural practices and organic pollution. Science of the Total Environment, 341(1-3): 265-279.
[22] Gregorich E G, McLaughlin N B, Lapen D R, et al.2014. Soil compaction, both an environmental and agronomic culprit: Increased nitrous oxide emissions and reduced plant nitrogen uptake. Soil Science Society of America Journal, 78(6): 1913-1923.
[23] Gregory A S, Watts C W, Whalley W R, et al.2007. Physical resilience of soil to field compaction and the interactions with plant growth and microbial community structure. European Journal of Soil Science, 58(6): 1221-1232.
[24] Gómez-Sagasti M, Alkorta I, Becerril J M, et al.2012. Microbial monitoring of the recovery of soil quality during heavy metal phytoremediation. Water, Air & Soil Pollution, 223(6): 3249-3262.
[25] Grzesiak M T.2009. Impact of soil compaction on root architecture, leaf water status, gas exchange and growth of maize and triticale seedlings. Plant Root, 3: 10-16.
[26] Jackson M L.1967. Soil Chemical Analysis. New Delhi: Prentice-Hall of Indian Pvt. Ltd.
[27] Jiao C Q, Wang Y Q, Liu J, et al.2009. Spatial-temporal variability of soil hardness and effect of soil hardness on other soil properties in rotary tillage in Guanzhong farmland. Agricultural Research in the Arid Areas, 27(3): 7-12. (in Chinese)
[28] Jones R J A, Spoor G, Thomasson A J.2003. Vulnerability of subsoil’s in Europe to compaction: a preliminary analysis. Soil and Tillage Research, 73(1-2): 131-143.
[29] Kristoffersen A ?, Riley H.2005. Effects of soil compaction and moisture regime on the root and shoot growth and phosphorus uptake of barley plants growing on soils with varying phosphorus status. Nutrient Cycling in Agroecosystems, 72(2): 135-146.
[30] Labud V, Garcia C, Hernandez T.2007. Effect of hydrocarbon pollution on the microbial properties of a sandy and a clay soil. Chemosphere, 66(10): 1863-1871.
[31] Li C L, Xu J B, He Y Q, et al.2012. Dynamic relationship between biologically active soil organic carbon and aggregate stability in long-term organically fertilized soils. Pedosphere, 22(5): 616-622.
[32] Li F S, Wei C H, Zhang F C, et al.2010. Water-use ef?ciency and physiological responses of maize under partial root-zone irrigation. Agricultural Water Management, 97(8): 1156-1164.
[33] Li H, Zhang Y, Zhang C G, et al.2005. Effect of petroleum-containing wastewater irrigation on bacterial diversities and enzymatic activities in a paddy soil irrigation area. Journal of Environmental Quality, 34(3): 1073-1080.
[34] Liang Q, Chen H Q, Gong Y S, et al.2012. Effects of 15 years of manure and inorganic fertilizers on soil organic carbon fractions in a wheat-maize system in the North China Plain. Nutrient Cycling in Agroecosystems, 92(1): 21-33.
[35] Liang Y C, Yang Y F, Yang C G, et al.2003. Soil enzymatic activity and growth of rice and barley as influenced by organic manure in an anthropogenic soil. Geoderma, 115(1-2): 149-160.
[36] Marinari S, Masciandaro G, Ceccanti B, et al.2000. Influence of organic and mineral fertilisers on soil biological and physical properties. Bioresoruce Technology, 72: 9-17.
[37] Masto R E, Chhonkar P K, Singh D, et al.2008. Changes in soil quality indicators under long-term sewage irrigation in a sub-tropical environment. Environmental Geology, 56(6): 1237-1243.
[38] Mitchell C C, Westerman R L, Brown J R, et al.1991. Overview of long-term agronomic research. Agronomy Journal, 83(1): 24-29.
[39] Mooney S J, Nipattasuk W.2003. Quantification of the effects of soil compaction on water flow using dye tracers and image analysis. Soil Use and Management, 19(4): 356-363.
[40] Nannipieri P, Kandeler E, Ruggiero P. 2002. Enzyme activities and microbiological and biochemcial processes in soil. In: Burns R G, Dick R P. Enzymes in the Environment. New York: Marcel Dekker, 1-33.
[41] Nawaz M F, Bourrié G, Trolard F.2013. Soil compaction impact and modelling. A review. Agronomy for Sustainable Development, 33(2): 291-309.
[42] Ogle S M, Breidt F J, Eve M D, et al.2003. Uncertainty in estimating land use and management impacts on soil organic carbon storage for US agricultural lands between 1982 and 1997. Global Change Biology, 9(11): 1521-1542.
[43] Ogle S M, Breidt F J, Paustian K.2005. Agricultural management impacts on soil organic carbon storage under moist and dry climatic conditions of temperate and tropical regions. Biogeochemistry, 72(1): 87-121.
[44] Rezapour S, Samadi A.2012. Soil quality response to long-term wastewater irrigation in Inceptisols from a semi-arid environment. Nutrient Cycling in Agroecosystems, 91(3): 269-280.
[45] Schj?nning P, Christensen B T, Carstensen B.1994. Physical and chemical properties of s sandy loam receiving animal manure, mineral fertilizer or no fertilizer for 90 years. European Journal of Soil Science, 45(3): 257-268.
[46] Schroth G, Sinclair F L. 2003. Trees, Crops and Soil Fertility Concepts and Research Methods. London: CABI Publishing, 77-91.
[47] Shen G P, Lu Y T, Zhou Q X, et al.2005. Interaction of polycyclic aromatic hydrocarbons and heavy metals on soil enzyme. Chemosphere, 61(8): 1175-1182.
[48] Siggins A, Burton V, Ross C, et al.2016. Effects of long-term greywater disposal on soil: A case study. Science of the Total Environment, 557-558: 627-635.
[49] Smith O H, Petersen G W, Needelman B A.2000. Environmental indicators of agroecosystems. Advances in Agronomy, 69: 75-97.
[50] Sun H Y, Wang C X, Wang X D, et al.2013. Changes in soil organic carbon and its chemical fractions under different tillage practices on loess soils of the Guanzhong Plain in north-west China. Soil Use and Management, 29(3): 344-353.
[51] Szolnoki Z, Farsang A, Puskás I.2013. Cumulative impacts of human activities on urban garden soils: origin and accumulation of metals. Environmental Pollution, 177: 106-115.
[52] Tabatabai M A, Bremner J M.1969. Use of p-nitrophenol phosphate for assay of soil phosphatase activity. Soil Biology and Biochemistry, 1(4): 301-307.
[53] Tabatabai M A, Bremner J M.1972. Assay of urease activity in soils. Soil Biology and Biochemistry, 4(4): 479-487.
[54] Tang K L.2003. China Water and Soil Conservation. Beijing: Science Press, 845. (in Chinese)
[55] Tobia?ová E.2011. The effect of organic matter on the structure of soils of different land uses. Soil and Tillage Research, 114(2): 183-192.
[56] Twnm E K A, Nii-Annang S. 2015. Impact of soil compaction on bulk density and root biomass of Quercus petraea L. at reclained post-lignite mining site in Lusatia, Germany. Applied and Environmental Soil Science, 2015: 504603.
[57] Verma B C, Datta S P, Rattan R K, et al.2010. Monitoring changes in soil organic carbon pools, nitrogen, phosphorus, and sulfur under different agricultural management practices in the tropics. Environmental Monitoring and Assessment, 171(1-4): 579-593.
[58] Wang Y F, Fu B J, Lü Y H, et al.2010. Local-scale spatial variability of soil organic carbon and its stock in the hilly area of the Loess Plateau, China. Quaternary Research, 73(1): 70-76.
[59] Yaalon D H, Yaron B.1966. Framework for man-made soil changes-an outline of metapedogenesis. Soil Science, 102(4): 272-277.
[60] Zhang C, Liu G B, Xue S, et al.2013. Soil organic carbon and total nitrogen storage as affected by land use in a small watershed of the Loess Plateau, China. European Journal of Soil Biology, 54: 16-24.
[61] Zhang J, Sui Y H. 2011. Changes of active soil organic carbon under different growing stages of Chinese fir plantation. In: 2011 International Conference on New Technology of Agricultural Engineering (ICAE). Zibo: IEEE, 609-612.
[62] Zhang L H, Xie Z K, Zhao R F, et al.2012. The impact of land use change on soil organic carbon and labile organic carbon stocks in the Longzhong region of Loess Plateau. Journal of Arid Land, 4(3): 241-250.
[63] Zhou Z C, Zhang X Y, Gan Z T.2015. Changes in soil organic carbon and nitrogen after 26 years of farmland management on the Loess Plateau of China. Journal of Arid Land, 7(6): 806-813.
[64] Mazzoncini M, Sapkota T B, Bàrberi P, et al.2011. Long-term effect of tillage, nitrogen fertilization and cover crops on soil organic carbon and total nitrogen content. Soil and Tillage Research, 114(2): 165-174.
[65] Zhu X M.1989. Soil and Agriculture in the Loess Plateau. Beijing: Agricultural Press, 248-253. (in Chinese)
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