Spatial variability of soil properties in red soil and its implications for site-specific fertilizer management

doi:10.1016/S2095-3119(20)63221-X

摘要/Abstract

Abstract:

Assessing spatial variability and mapping of soil properties constitute important prerequisites for soil and crop management in agricultural areas. To explore the relationship between soil spatial variability and land management, 256 samples were randomly collected at two depths (surface layer 0–20 cm and subsurface layer 20–40 cm) under different land use types and soil parent materials in Yujiang County, Jiangxi Province, a red soil region of China. The pH, soil organic matter (SOM), total nitrogen (TN), cation exchange capacity (CEC), and base saturation (BS) of the soil samples were examined and mapped. The results indicated that soils in Yujiang were acidified, with an average pH of 4.87 (4.03–6.46) in the surface layer and 4.99 (4.03–6.24) in the subsurface layer. SOM and TN were significantly higher in the surface layer (27.6 and 1.50 g kg^–1, respectively) than in the subsurface layer (12.1 and 0.70 g kg^–1, respectively), while both CEC and BS were low (9.0 and 8.0 cmol kg^–1, 29 and 38% for surface and subsurface layers, respectively). Paddy soil had higher pH (mean 4.99) than upland and forest soils, while soil derived from river alluvial deposits (RAD) had higher pH (mean 5.05) than the other three parent materials in both layers. Geostatistical analysis revealed that the best fit models were exponential for pH and TN, and spherical for BS in both layers, while spherical and Gaussian were the best fitted for SOM and CEC in the surface and subsurface layers. Spatial dependency varied from weak to strong for the different soil properties in both soil layers. The maps produced by selecting the best predictive variables showed that SOM, TN, and CEC had moderate levels in most parts of the study area. This study highlights the importance of site-specific agricultural management and suggests guidelines for appropriate land management decisions.

Key words: spatial variability , soil pH , CEC , BS , site-specific fertilizer management

. [J]. Journal of Integrative Agriculture, 2020, 19(9): 2313-2325.

SONG Fang-fang, XU Ming-gang, DUAN Ying-hua, CAI Ze-jiang, WEN Shi-lin, CHEN Xian-ni, SHI Wei-qi, Gilles COLINET. Spatial variability of soil properties in red soil and its implications for site-specific fertilizer management[J]. Journal of Integrative Agriculture, 2020, 19(9): 2313-2325.

参考文献

Armstrong M, Boufassa A. 1988. Comparing the robustness of ordinary kriging and lognormal kriging: Outlier resistance. Mathematical Geology, 20, 447–457.
Behera S K, Shukla A K. 2015. Spatial distribution of surface soil acidity, electrical conductivity, soil organic carbon content and exchangeable potassium, calcium and magnesium in some cropped acid soils of India. Land Degradation Development, 26, 71–79.
Blanchet G, Libohova Z, Joost S, Rossier N, Schneider A, Jeangros B, Sinaj S. 2017. Spatial variability of potassium in agricultural soils of the canton of Fribourg, Switzerland. Geoderma, 290, 107–121.
Bogunovic I, Mesic M, Zgorelec Z, Jurisic A, Bilandzija D. 2014. Spatial variation of soil nutrients on sandy-loam soil. Soil & Tillage Research, 144, 174–183.
Bogunovic I, Pereira P, Brevik E C. 2017. Spatial distribution of soil chemical properties in an organic farm in Croatia. Science of the Total Environment, 584–585, 535–545.
Bowman W D, Cleveland C C, Halada ?, Hreško J, Baron J S. 2008. Negative impact of nitrogen deposition on soil buffering capacity. Nature Geoscience, 1, 767–770.
Cai Z J, Wang B R, Xu M G, Zhang H M, He X H, Zhang L, Gao S D. 2015. Intensified soil acidification from chemical N fertilization and prevention by manure in an 18-year field experiment in the red soil of southern China. Journal of Soils and Sediments, 15, 260–270.
Cambardella C A, Moorman T B, Parkin T B, Karlen D L, Novak J M, Turco R F, Konopka A E. 1994. Field-scale variability of soil properties in central Iowa soils. Soil Science Society of America Journal, 58, 1501–1511.
Chen D M, Lan Z C, Bai X, Grace J B, Bai Y F. 2013. Evidence that acidification-induced declines in plant diversity and productivity are mediated by changes in below-ground communities and soil properties in a semi-arid steppe. Journal of Ecology, 101, 1322–1334.
Denton O A, Aduramigba-Modupe V O, Ojo A O, Adeoyolanu O D, Are K S, Adelana A O, Oyedele A O, Adetayo A O, Oke A O. 2017. Assessment of spatial variability and mapping of soil properties for sustainable agricultural production using geographic information system techniques (GIS). Cogent Food & Agriculture, 3, 1–12.
Duan L, Huang Y M, Hao J M, Xie S D, Hou M. 2004. Vegetation uptake of nitrogen and base cations in China and its role in soil acidification. Science of the Total Environment, 330, 187–198.
Ferreiro J P, de Almeida V P, Alves M C, de Abreu C A, Vieira S R, Vázquez E V. 2016. Spatial variability of soil organic matter and cation exchange capacity in an Oxisol under different land uses. Communications in Soil Science and Plant Analysis, 47, 75–89.
Fu W J, Tunney H, Zhang C S. 2010. Spatial variation of soil nutrients in a dairy farm and its implications for site-specific fertilizer application. Soil & Tillage Research, 106, 185–193.
Fujii K, Hayakawa C, Panitkasate T, Maskhao I, Funakawa S, Kosaki T, Nawata E. 2017. Acidification and buffering mechanisms of tropical sandy soil in northeast Thailand. Soil Tillage Research, 165, 80–87.
Gelaw A M, Singh B R, Lal R. 2014. Soil organic carbon and total nitrogen stocks under different land uses in a semi-arid watershed in Tigray, Northern Ethiopia. Agriculture, Ecosystems and Environment, 188, 256–263.
Gruba P, Socha J. 2016. Effect of parent material on soil acidity and carbon content in soils under silver fir (Abies alba Mill.) stands in Poland. Catena, 140, 90–95.
Guan F Y, Xia M P, Tang X L, Fan S H. 2017. Spatial variability of soil nitrogen, phosphorus and potassium contents in Moso bamboo forests in Yong’an City, China. Catena, 150, 161–172.
Guo J H, Liu X J, Zhang Y, Shen J L, Han W X, Zhang W F, Christie P, Goulding K W T, Vitousek P M, Zhang F S. 2010. Significant acidification in major Chinese croplands. Science, 327, 1008–1010.
Guo X, Li H Y, Yu H M, Li W F, Ye Y C, Biswas A. 2018. Drivers of spatio-temporal changes in paddy soil pH in Jiangxi Province, China from 1980 to 2010. Scientific Reports, 8, 1–11.
Hanway J J, Heidel H. 1952. Soil analysis methods as used in Iowa state college soil testing laboratory. Iowa Agriculture, 57, 1–31.
Hao T X, Zhu Q C, Zeng M F, Shen J L, Shi X J, Liu X J, Zhang F S, de Vries W. 2018. Quantification of the contribution of nitrogen fertilization and crop harvesting to soil acidification in a wheat-maize double cropping system. Plant and Soil, 434, 167–184.
Hengl T, Heuvelink G B M, Stein A. 2004. A generic framework for spatial prediction of soil variables based on regression-kriging. Geoderma, 120, 75–93.
Horswill P, O’Sullivan O, Phoenix G K, Lee J A, Leake J R. 2008. Base cation depletion, eutrophication and acidification of species-rich grasslands in response to long-term simulated nitrogen deposition. Environmental Pollution, 155, 336–349.
IUSS Working Group. 2015. World Reference Base for Soil Resources 2014, Update 2015: International Soil Classification System for Naming Soils and Creating Legends for Soil Maps. World Soil Resources Reports No. 106. FAO, Rome.
Jones Jr J B. 1998. Soil test methods: Past, present, and future use of soil extractants. Communications in Soil Science and Plant Analysis, 29, 1543–1552.
Kerry R, Oliver M A. 2007. Comparing sampling needs for variograms of soil properties computed by the method of moments and residual maximum likelihood. Geoderma, 140, 383–396.
Li Q Q, Li S, Xiao Y, Zhao B, Wang C Q, Li B, Gao X S, Li Y D, Bai G C, Wang Y D, Yuan D G. 2019. Soil acidification and its influencing factors in the purple hilly area of southwest China from 1981 to 2012. Catena, 175, 278–285.
Liu S L, Li Y, Wu J S, Huang D Y, Su Y R, Wei W X. 2010. Spatial variability of soil microbial biomass carbon, nitrogen and phosphorus in a hilly red soil landscape in subtropical China. Soil Science and Plant Nutrition, 56, 693–704.
Liu Z P, Shao M A, Wang Y Q. 2013. Spatial patterns of soil total nitrogen and soil total phosphorus across the entire Loess Plateau region of China. Geoderma, 197–198, 67–78.
Matocha C J, Grove J H, Karathanasis T D, Vandiviere M. 2016. Changes in soil mineralogy due to nitrogen fertilization in an agroecosystem. Geoderma, 263, 176–184.
Mayes M, Marin-Spiotta E, Szymanski L, Akif Erdo?an M, Ozdo?an M, Clayton M. 2014. Soil type mediates effects of land use on soil carbon and nitrogen in the Konya Basin, Turkey. Geoderma, 232–234, 517–527.
Mcgahan D G, Southard R J, Zasoski R J. 2003. Mineralogical comparison of agriculturally acidified and naturally acidic soils. Geoderma, 114, 355–368.
Mousavifard S M, Momtaz H, Sepehr E, Davatgar N, Sadaghiani M H R. 2013. Determining and mapping some soil physico-chemical properties using geostatistical and GIS techniques in the Naqade region, Iran. Archives of Agronomy and Soil Science, 59, 1573–1589.
Nsor M E, Ibanga I J. 2009. Influence of parent materials on the physico-chemical properties of soils in Central Cross River State, Nigeria. Global Journal of Agricutural Sciences, 7, 183–190.
Page A L. 1965. Methods of soil analysis. Part 2. In: Chemical and Microbiological Properties. American Society of Agronomy, Soil Science Society of America, USA.
Pebesma E J. 2004. Multivariable geostatistics in S: The gstat package. Computers & Geosciences, 30, 683–691.
Qu M K, Li W D, Zhang C R, Wang S Q. 2012. Effect of land use types on the spatial prediction of soil nitrogen. GIScience & Remote Sensing, 49, 397–411.
R Core Team. 2017. R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. [2017-06-30]. https://www.R-project.org/
Ramirez K S, Lauber C L, Knight R, Bradford M A, Fierer N. 2010. Consistent effects of nitrogen fertilization on soil bacterial communities in contrasting systems. Ecology, 91, 3463–3470.
Revelle W. 2018. Psych: Procedures for personality and psychological research, Northwestern University, Evanston, Illinois, USA. [2018-05-06]. https://CRAN.R-project.org/package=psych
Robert J H. 2017. Raster: Geographic data analysis and modeling. R package version 2.6-7. [2017-11-13]. https://CRAN.R-project.org/package=raster
Rosemary F, Vitharana U W A, Indraratne S P, Weerasooriya R, Mishra U. 2017. Exploring the spatial variability of soil properties in an Alfisol soil catena. Catena, 150, 53–61.
Song W F, Wang C, Chen R F, Wen S L, Wang B R, Shen R F. 2017. Comparison of contribution of wheat ionic uptake to soil acidification under different long-term fertilization. Soils, 49, 7–12. (in Chinese)
Sun B, Zhou S L, Zhao Q G. 2003. Evaluation of spatial and temporal changes of soil quality based on geostatistical analysis in the hill region of subtropical China. Geoderma, 115, 85–99.
SSOYC (Soil Survey Office of Yujiang County). 1986. The Soils of Yujiang County. Office of Soil Survey in Jiangxi Province, Nanchang. (in Chinese)
Tang X L, Xia M P, Pérez-Cruzado C, Guan F Y, Fan S H. 2017. Spatial distribution of soil organic carbon stock in Moso bamboo forests in subtropical China. Scientific Reports, 7, 1–13.
Tesfahunegn G B, Tamene L, Vlek P L G. 2011. Catchment-scale spatial variability of soil properties and implications on site-specific soil management in northern Ethiopia. Soil & Tillage Research, 117, 124–139.
Ulrich B. 1986. Natural and anthropogenic components of soil acidification. Journal of Plant Nutrition and Soil Science, 149, 702–717.
Vasu D, Singh S K, Sahu N, Tiwary P, Chandran P, Duraisami V P, Ramamurthy V, Lalitha M, Kalaiselvi B. 2017. Assessment of spatial variability of soil properties using geospatial techniques for farm level nutrient management. Soil & Tillage Research, 169, 25–34.
De Vries W, Breeuwsma A. 1987. The relation between soil acidification and element cycling. Water, Air, and Soil Pollution, 35, 293–310.
Wang Q, Yu H Y, Liu J F, Li F B. 2018. Attribution of soil acidification in a large-scale region: Artificial intelligence approach application. Soil Science Society of America Journal, 82, 772–782.
Wilding L P. 1985. Spatial variability: Its documentation, accommodation and implication to soil surveys. In: Soil Spatial Variability Workshop. Wageningen, The Netherlands. pp. 166–194.
Xu S X, Shi X Z, Wang M Y, Zhao Y C. 2016. Effects of subsetting by parent materials on prediction of soil organic matter content in a hilly area using vis-NIR spectroscopy. PLoS ONE, 11, 1–17.
Yang P G, Byrne J M, Yang M. 2016. Spatial variability of soil magnetic susceptibility, organic carbon and total nitrogen from farmland in northern China. Catena, 145, 92–98.
Zhang H X, Zhuang S Y, Qian H Y, Wang F, Ji H B. 2015. Spatial variability of the topsoil organic carbon in the Moso bamboo forests of southern China in association with soil properties. PLoS ONE, 10, e0119175.
Zhang S L, Huffman T, Zhang X Y, Liu W, Liu Z H. 2014. Spatial distribution of soil nutrient at depth in black soil of Northeast China: A case study of soil available phosphorus and total phosphorus. Journal of Soils and Sediments, 14, 1775–1789.
Zhu Q C, de Vries W, Liu X J, Hao T X, Zeng M F, Shen J L, Zhang F S. 2018. Enhanced acidification in Chinese croplands as derived from element budgets in the period 1980–2010. Science of the Total Environment, 618, 1497–1505.