Variations of soil quality from continuously planting greenhouses in North China

Jing Li, Yan Xu, Hongguang Liu

Abstract


Vegetable greenhouses form a significant land utilisation pattern in China. A case study of the greenhouse soil quality changes and potential risk to humans under a specific long-term environment, which includes high fertilization rates, high temperatures and humidity levels and out-of-season cultivation, is presented in this study. Soil profiles of 72 representative solar greenhouses with various planting years were sampled in Shouguang City, which is the birthplace of winter greenhouse in China. The temporal distribution of soil quality changes were quantitatively evaluated through the application of a correlation analysis and soil quality assessment. The soil was highly enriched with phosphorus and potassium and had low organic matter content. The organic matter, nitrogen, phosphorus and potassium contents increased with the years planted, reached their peak values after 5-10 a, and declined as the soil layer’s depth increased. The infiltration rate of nitrate was relatively high, which poses risks to underground water safety. A comprehensive soil quality assessment revealed that in vegetable greenhouses planted for different periods, the soil quality improved at first and then sharply declined after 10 a. Studying greenhouse soil quality changes will aid in implementing nutrient management strategies to improve the soil quality and sustainable development programs for the vegetable industry.
Keywords: vegetable greenhouse, facility agriculture, planting years, soil quality, microbial activity
DOI: 10.25165/j.ijabe.20191201.4092

Citation: Li J, Xu Y, Liu H G. Variations of soil quality from continuously planting greenhouses in North China. Int J Agric & Biol Eng, 2019; 12(1): 139–145.

Keywords


vegetable greenhouse, facility agriculture, planting years, soil quality, microbial activity

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References


Zhang H, Hu K, Zhang L, Ji Y, Qin W. Exploring optimal catch crops for reducing nitrate leaching in vegetable greenhouse in North China. Agricultural Water Management, 2019; 212: 273–282.

Li M, Li J, Wei X, Zhu W. Early diagnosis and monitoring of nitrogen nutrition stress in tomato leaves using electrical impedance spectroscopy. International Journal of Agricultural and Biological Engineering, 2017; 10(3): 194–205.

Cao C, Chen X P, Ma Z B, Jia H H, Wang J J. Greenhouse cultivationmitigates metal-ingestion-associated health risks from vegetables in wastewater-irrigated agroecosystems. Science of the Total Environment, 2016; (560): 204–211.

Jiang C, Li Z, Zhang Y, Li M, Liu M. Quality assessment of greenhouse vegetable soils in suburbs of Nanjing city based on analyses of nutrient content and biochemical properties. Jiangsu Journal of Agricultural Sciences, 2014; 30(2): 296–303.

Zhang X, Zhang Q, Liang B, Li J. Changes in the abundance and structure of bacterial communities in the greenhouse tomato cultivation system under long-term fertilization treatments. Applied Soil Ecology, 2017; 121: 82–89.

Ministry of Rural Agriculture, On approving the thirteenth batch of fixed markets of the Ministry of Agriculture. http://www.moa.gov.cn/nybgb/ 2007/dseq/201806/t20180614_6152083.htm, 2007: Beijing.

Liu P, Li Y, Jiang L, Liu Z, Gao X, Lin H, Zheng F, et al. Effects of fertilizer application on greenhouse vegetable yield: A case study of Shouguang City. Chinese Journal of Applied Ecology, 2014; 25(6): 1752–1758.

Xu Y Q, Qin H L, Quan Z, Wei W X. Effects of long-term vegetable cultivation on the NO3--N contents in soil profile and groundwater. Research of Agricultural Modernization, 2015; 36(6): 1080–1085.

Chen Z, Tian T, Gao L, Tian Y. Nutrients, heavy metals and phthalate acid esters in solar greenhouse soils in Round-Bohai Bay-Region, China: impacts of cultivation year and biogeography. Environmental Science and Pollution Research, 2016; 23(13): 13076–13087.

Zhong W, Bian B, Gao N, Min J, Shi W, Lin X, Shen W. Nitrogen fertilization induced changes in ammonia oxidation are attributable mostly to bacteria rather than archaea in greenhouse-based high N input vegetable soil. Soil Biology & Biochemistry, 2016; 93: 150–159.

Zhang Y, Lin F, Jin Y, Wang X, Liu S, Zou J. Response of nitric and nitrous oxide fluxes to N fertilizer application in greenhouse vegetable cropping systems in southeast China. Scientific Reports, 2016; 6.20700

Vincent Q, Auclerc A, Beguiristain T, and Leyval C. Assessment of derelict soil quality: Abiotic, biotic and functional approaches. Science of the Total Environment, 2018; 613: 990–1002.

Li Y D, Effects of fertilization and planting years on vegetabel quality and soil microbes. 2014, North West Agriculture and Forestry University. Shanxi.

Myrold D D, Shaviv A. Advanced methods for investigating nutrient dynamics in soils and ecosystems. Soil Science Society of America Journal, 2014; 78(1): 1–2.

Du S, Gao X. Technical Specification for Soil Analysis 2006, Beijing: China Agricultural Press.

Zhan R S, Yue X L, Han Z P, Yang W, and Rong T T. Variation of nutrient contents in protected cultivation soil with different planting years in north area of Shanxi Province. Agricultural Research in the Arid Areas, 2012; 5: 133–137.

Yang Y, Zhang H, Shan Y, Wang J, Qian X, Meng T, et al. Response of denitrification in paddy soils with different nitrification rates to soil moisture and glucose addition. Science of the Total Environment, 2019; 651: 2097–2104.

Wang Z, Wang Z, Ma L J, Khattak W A, Hu W, Meng Y L, et al. Combined effects of nitrogen fertilizer and straw application on aggregate distribution and aggregate-associated organic carbon stability in an alkaline sandy loam soil. European Journal of Soil Science, 2018; 69(6): 1105–1116.

Shen H, Zou G Y. Parameters selection for evaluation of vegetable soil quality and its gradation. Chinese Journal of Soil Science, 2004; 5: 553–557.

Xue Y F, Shi Z Q. Characteristics of soil nutrient and heavy metal content with the different years of cultivation. Journal of Soil and Water Conservation, 2011; 4: 125–130.

Yu H Y, Li T X, Zhang X Z. Nutrient budget and soil nutrient status in greenhouse system. Scientia Agricultura Sinica, 2010(3): 514–522.

Liu H, Cao L, Xu C, Yang H, Li B. Distribution characteristics of soil organic carbon and nitrogen in farmland and adjacent natural grassland in Tibet. International Journal of Agricultural and Biological Engineering, 2016; 9(1): 135–145.

Plaza C, Zaccone C, Sawicka K, Mendez A M, Tarquis A, Gasco G, et al. Soil resources and element stocks in drylands to face global issues. Scientific Reports, 2018, 8.

Ayala-Orozco B, Gavito M E, Mora F, Siddique I, Balvanera P, Jaramillo V J, et al. Resilience of soil properties to land-use change in a tropical dry forest ecosystem. Land Degradation & Development, 2018; 29(2): 315–325.

Pincus L N, Ryan P C, Huertas F J, Alvarado G E. The influence of soil age and regional climate on clay mineralogy and cation exchange capacity of moist tropical soils: A case study from Late Quaternary chronosequences in Costa Rica. Geoderma, 2017; 308: 130–148.

Rosa S D, Silva C A, Moreira G, Maluf H J. Wheat nutrition and growth as affected by humic acid-phosphate interaction. Journal of Plant Nutrition and Soil Science, 2018; 181(6): 870–877.

Sarkar D, Baishya L K, Meitei C B, Naorem G C, Rahman F H. Can sustainability of maize-mustard cropping system be achieved through balanced nutrient management? Field Crops Research, 2018; 225: 9–21.

Ammari T G, Tahhan R, Al Sulebi N, Tahboub A, Ta'Any R A, Abubaker S. Impact of intensive greenhouse production system on soil quality. Pedosphere, 2015; 25(2): 282–293.

Wang Y, Zhang H, Tang J, Xu J, Kou T, Huang H. Accelerated phosphorus accumulation and acidification of soils under plastic greenhouse condition in four representative organic vegetable cultivation sites. Scientia Horticulturae, 2015; 195: 67–73.

Kunhikrishnan A, Thangarajan R, Bolan N S, Xu Y, Naidu R. Functional relationships of soil acidification, liming, and greenhouse gas flux. Advances in Agronomy,. Sparks, Editor, 2016; Vol 139, pp.1–71.

Ning C, Wang J, Cai K. The Effects of organic fertilizers on soil fertility and soil environmental quality: A Review. Ecology and Environmental Sciences, 2016; 25(1): 175–181.




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