Spatial Variability of Rainfed Wheat Production Under the Influence of Topography and Soil Properties in Loess-Derived Soils, Northern Iran (original) (raw)
References
Agricultural Ministry of Iran. (2014). Office of statistics and information technology, bureau of agricultural statistics and information technology statistics. (In Farsi).
Ajami, M., Heidari, A., Khormali, F., Gorji, M., & Ayoubi, S. (2016). Environmental factors controlling soil organic carbon storage in loess soils of a subhumid region, northern Iran. Geoderma,281, 1–10. CAS Google Scholar
Ajami, M., Heidari, A., Khormali, F., Gorji, M., & Ayoubi, S. (2018). Effects of environmental factors on classification of loess-derived soils and clay minerals variations, northern Iran. Journal of Mountain Science,15(5), 976–991. Google Scholar
Antoneli, V., Mosele, A. C., Bednarz, J. A., Pulido-Fernández, M., Lozano-Parra, J., Keesstra, S. D., et al. (2019). Effects of applying liquid swine manure on soil quality and yield production in tropical soybean crops (Paraná, Brazil). Sustainability,11(14), 3898. Google Scholar
Ayoubi, S., Khormali, F., & Sahrawat, K. L. (2009). Relationships of barley biomass and grain yields to soil properties within a field in the arid region: Use of factor analysis. Acta Agriculturae Scandinavica Section B-Soil and Plant Science,59, 107–117. CAS Google Scholar
Basso, B., Ritchie, J. T., Cammarano, D., & Sartori, L. (2011). A strategic and tactical management approach to select optimal N fertilizer rates for wheat in a spatially variable field. European Journal of Agronomy,35, 215–222. Google Scholar
Bouyoucos, G. J. (1962). Hydrometer method improved for making particle size analysis of soils. Agronomy Journal,54, 464–465. Google Scholar
Bremner, J. M. (1996). Nitrogene-total. In J. T. Bigham, et al. (Eds.), Methods of soil analyses, part III, chemical methods (pp. 1085–1184). Madison: SSSA. Google Scholar
Cerdà, A., & Rodrigo-Comino, J. (2019). Is the hillslope position relevant for runoff and soil loss activation under high rainfall conditions in vineyards? Ecohydrology & Hydrobiology,20, 59–72. Google Scholar
Chapman, H. D. (1965). Cation exchange capacity. In C. A. Black (Ed.), Methods of soil analysis. Part 2. Madison: American Society of Agronomy. Google Scholar
Chirinda, N., Roncossek, S. D., Heckrath, G., Elsgaard, L., Thomsen, I. K., & Olesen, J. E. (2014). Root and soil carbon distribution at shoulder slope and foot slope positions of temperate toposequences cropped to winter wheat. CATENA,123, 99–105. CAS Google Scholar
Ciha, A. J. (1984). Slope position and grain yield of soft white winter wheat. Agronomy Journal,76, 193–196. Google Scholar
Cox, M. S., Gerard, P. D., Wardlaw, M. C., & Abshire, M. J. (2003). Variability of selected soil properties and their relationships with soybean yield. Soil Science Society America Journal,67, 1296–1302. CAS Google Scholar
ESRI. (2011). ArcGIS desktop: release 10. Redlands: Environmental Systems Research Institute. Google Scholar
Evrendliek, F., Celik, I., & Kilic, S. (2004). Changes in soil organic carbon and other physical soil properties along adjacent Mediterranean forests, grassland and cropland ecosystems. Journal of Arid Environments,59, 743–752. Google Scholar
Ferrara, R., Trevisiol, P., Acutis, M., Rana, G., Richter, G., & Baggaley, N. (2010). Topographic impacts on wheat yields under climate change: two contrasted case studies in Europe. Theoretical and Applied Climatology,99(1–2), 53–65. Google Scholar
Florinsky, I. V., Eilers, R. G., Manning, G. R., & Fuller, L. G. (2002). Prediction of soil properties by digital terrain modelling. Environment Modelling & Software,17, 295–311. Google Scholar
Ghosh, B. N., Sharma, N. K., Alam, N. M., Singh, R. J., & Juyal, G. P. (2014). Elevation, slope aspect and integrated nutrient management effects on crop productivity and soil quality in North-west Himalayas, India. Journal of Mountain Science,11(5), 1208–1217. Google Scholar
He, Y., Wei, Y., DePauw, R., Qian, B., Lemke, R., Singh, A., et al. (2013). Spring wheat yield in the semiarid Canadian prairies: Effects of precipitation timing and soil texture over recent 30 years. Field Crops Research,149, 329–337. Google Scholar
Iqbal, J., Read, J. J., Thomasson, A. J., & Jenkins, J. N. (2005). Relationships between soil-landscape and dryland cotton lint yield. Soil Science Society America Journal,69, 1–11. Google Scholar
Jalota, S. K., Singh, S., Chahal, G. B. S., Ray, S. S., Panigraghy, S., Singh, B., et al. (2010). Soil texture, climate and management effects on plant growth, grain yield and water use by rainfed maize-wheat cropping system: Field and simulation study. Agricultural Water Management,97, 83–90. Google Scholar
Jiang, P., & Telen, K. D. (2004). Effect of soil and topographic properties on crop yield in a north-central corn soybean cropping system. Agronomy Journal,96, 252–258. Google Scholar
Johnen, T., Boettcher, U., & Kage, H. (2014). An analysis of factors determining spatial variable grain yield of winter wheat. European Journal of Agronomy,52, 297–306. Google Scholar
Kemper, W. D., & Rosenau, R. C. (1986). Aggregate stability and size distribution. In A. Klute (Ed.), Methods of soil analysis. Part I: Physical analysis (pp. 425–442). Madison: Soil Science Society of America. Google Scholar
Khajehpour, M. R. (2013). Cereal crops. Isfahan: Isfahan University of Technology. (In Farsi). Google Scholar
Kravchenko, A. N., & Bullock, D. G. (2000). Correlation of corn and soybean grain yield with topography and soil properties. Agronomy Journal,92, 75–83. Google Scholar
Kravchenko, A. N., Robertson, G. P., Thelen, K. D., & Harwood, R. R. (2005). Management, topographical, and weather effects on spatial variability of crop grain yields. Agronomy Journal,97, 514–523. Google Scholar
Kumhálová, J., Matejkova, S., Fifernová, M., Lipavsky, J., & Kumhála, F. (2008). Topography impact on nutrition content in soil and yield. Plant Soil Environment,54(6), 255. Google Scholar
Malakouti, M. J., Keshavarz, P., & Karimian, N. (2008). A comprehensive approach towards identification of nutrients deficiencies and optimal fertilization for sustainable agriculture. Tehran: Tarbiat Modares University Press. (In Farsi). Google Scholar
McLean, E. O. (1982). Soil pH and lime requirement. In Page, A. L., Miller, R. H., & Keeney, D. R. (Eds.), Methods of soil analysis, part 2. Chemical and microbiological properties (2nd ed., vol. 9, pp. 199–224). Agronomy.
Mehnatkesh, A. (2014). Determination of the most important factors on rainfed wheat production using sensitivity analysis in hilly land of central Zagros. In First National Conference on soil and water management in wheat production Tehran, Iran (In Farsi).
Mohammadi, J. (2008). Pedometrics (Trrain analysis). Warsaw: Pelk publications. (In Farsi). Google Scholar
Nabiollahi, K., Taghizadeh-Mehrjardi, R., & Eskandari, S. (2018). Assessing and monitoring the soil quality of forested and agricultural areas using soil-quality indices and digital soil-mapping in a semi-arid environment. Archives of Agronomy and Soil Science, 64(5), 696–707. Google Scholar
Nelson, D. W., & Sommers, L. E. (1982). Total carbon, organic carbon and organic matter. In Page, A. L., Miller, R. H., Keeney, D. R. (Eds.), Methods of soil analysis, part 2. Chemical and microbiological properties (2nd ed., vol. 9, pp. 539–579). Agronomy.
Norouzi, M., Ayoubi, S., Jalalian, A., Khademi, H., & Dehghani, A. A. (2010). Predicting rainfed wheat quality and quantity by artificial neural network using terrain and soil characteristics. Acta Agriculturae Scandinavica Section B-Soil and Plant Science,60(4), 341–352. CAS Google Scholar
Noruzi, M., Jalalian, A., Ayoubi, Sh, & Khademi, H. (2009). Relationship between wheat yield and terrain attributes in Ardal Region, Charmahal and Bakhtiari Province. Journal of Science and Technology of Agriculture and Natural Resources,12(46), 759–770. (In Farsi). Google Scholar
Nour-Mohammadi, G., Siadat, A., & Kashani, A. (1997). Agronomy (vol. 1: Cereal crops). Ahwaz: Shahid Chamran University. (In Farsi). Google Scholar
Olaya, V. (2004). A gentle introduction to SAGA GIS (p. 208). Gottingen: The SAGA User Group eV. Google Scholar
Olsen, S. R., Cole, C. V., Watanabe, F. S., & Dean, L. A. (1954). Estimation of available P in soils by extraction with sodium bicarbonate. USDA Circular,939, 1–19. Google Scholar
Page, A. L., Miller, R. H., & Keeney, D. R. (1982). Methods of soil analysis. Part 2: Chemical and biological properties (2nd ed.). Madison: SSSA. Google Scholar
Pan, G., Smith, P., & Pan, W. (2009). The role of soil organic matter in maintaining the productivity and yield stability of cereals in China. Agriculture, Ecosystems & Environment,129, 344–348. Google Scholar
Plante, A. F., Conant, R. T., Stewart, C. E., Paustian, K., & Six, J. (2006). Impact of soil texture on the distribution of soil organic matter in physical and chemical fractions. Soil Science Society of America Journal,70, 287–296. CAS Google Scholar
Qiu, Y., Fu, B., Wang, J., & Chen, L. (2001). Soil moisture variation in relation to topography and land use in a hillslope catchment of the Loess Plateau, China. Journal of Hydrology,240(3–4), 243–263. Google Scholar
Reyniers, M., Maertens, K., Vrindts, E., & De Baerdemaeker, J. (2006). Yield variability related to landscape properties of a loamy soil in central Belgium. Soil and Tillage Research,88, 262–273. Google Scholar
Richards, L. A. (1954). Diagnosis and improvement of saline and alkaline soil. USDA Handbook, No. 60, Washington, DC.
Rodrigo-Comino, J. (2018). Five decades of soil erosion research in “terroir” The State-of-the-Art. Earth-Science Reviews,179, 436–447. Google Scholar
Rodrigo-Comino, J., Keshavarzi, A., Zeraatpisheh, M., Gyasi-Agyei, Y., & Cerdà, A. (2019). Determining the best ISUM (Improved stock unearthing Method) sampling point number to model long-term soil transport and micro-topographical changes in vineyards. Computers and Electronics in Agriculture,159, 147–156. Google Scholar
Rodrigo-Comino, J., Senciales, J., Ramos, M. A., Martínez-Casasnovas, J. A., Lasanta, T., Brevik, E. C., et al. (2017). Understanding soil erosion processes in Mediterranean sloping vineyards (Montes de Málaga, Spain). Geoderma,296, 47–59. Google Scholar
Salinity Laboratory Staff. (1954). Diagnosis and improvement of saline and alkali soils, no. 60. Washington DC: USDA-NRCS. Google Scholar
Shabani, A., Haghnia, Gh, Karimi, A., & Ahmadi, M. M. (2012). Influence of topography and soil characteristics on the rainfed wheat yield in Sisab Region, Northeastern Iran. Journal of Water Soil,26(4), 922–932. (In Farsi). Google Scholar
Sinai, G., Zaslavsky, D., & Golany, P. (1981). The effect of soil surface curvature on moisture and yield-Beer Sheba observation. Soil Science,132(5), 367–375. Google Scholar
Slobodian, N., VanRees, K., & Pennock, D. (2002). Cultivation-induced effects on belowground biomass and organic carbon. Soil Science Society America Journal,66, 924–930. CAS Google Scholar
Soil and Water Research Institute of Iran. (2000). Soil resources and use potentiality map of Iran (1:1000000), Tehran.
Soil Survey Staff. (2014). Keys to Soil Taxonomy (12th ed.). Washington, DC: United States Department of Agriculture (USDA), Natural Resources Conservation Service (NRCS). Google Scholar
Solomon, D., Fritzsche, F., Tekalign, M., Lemann, J., & Zech, W. (2002). Soil organic matter composition in the subhumid Ethiopian highlands as influenced by deforestation and agricultural management. Soil Science Society America Journal,66, 68–82. CAS Google Scholar
Souza, Z. M., Cerri, D. G. P., Magalhes, P. S. G., & Siqueira, D. S. (2010). Spatial variability of soil attributes and sugarcane yield in relation to topographic location. Engenharia Agricolae Ambiental,14, 1250–1256. Google Scholar
Taghizadeh-Mehrjardi, R., Schmidt, K., Amirian-Chakan, A., Rentschler, T., Zeraatpisheh, M., Sarmadian, F., et al. (2020a). Improving the spatial prediction of soil organic carbon contentin two contrasting climatic regions by stacking machine learning models and rescanning covariate space. Remote Sensing, 12(7), 1095. Google Scholar
Taghizadeh-Mehrjardi, R., Nabiollahi, K., Rasoli, L., Kerry, R., & Scholten, T. (2020b). Land suitability assessment and agricultural production sustainability using machine learning models. Agronomy, 10(4), 573. Google Scholar
Timlin, D. J., Pachepsky, Y., Snyder, V. A., & Bryant, R. B. (1998). Spatial and temporal variability of corn grain yield on a hillslope. Soil Science Society America Journal,62(3), 764–773. CAS Google Scholar
USDA (United States Department of Agriculture). (1998). Soil quality information sheet. Washington, DC: Soil Quality Resource Concerns: Soil Biodiversity. Google Scholar
VanWambeke, A. (1992). Soils of the tropics—properties and appraisal. New York: McGraw-Hill. Google Scholar
Wezel, A., Steinmüller, N., & Friederichsen, J. (2002). Slope position effects on soil fertility and crop productivity and implications for soil conservation in upland northwest Vietnam. Agriculture, Ecosystems & Environment,91(1–3), 113–126. Google Scholar
Zeraatpisheh, M., Ayoubi, S., Sulieman, M., & Rodrigo-Comino, J. (2019). Determining the spatial distribution of soil properties using the environmental covariates and multivariate statistical analysis: a case study in semi-arid regions of Iran. Journal of Arid Land,11(4), 551–566. Google Scholar
Zeraatpisheh, M., Bakhshandeh, E., Hosseini, M., & Alavi, S. M. (2020). Assessing the effects of deforestation and intensive agriculture on the soil quality through digital soil mapping. Geoderma,363, 114139. CAS Google Scholar