Soil Nutrient Relationships with Topography as Influenced by Crop

Variable-rate fertilizer application is often based on grid soil sample data from a single year of data in an annual crop rotation. The objectives of this study were to determine if crop history influences spatial dependence (the degree of spatial variability) of nutrients in a rotation including both annual crops and alfalfa, and to compare grid-based and topography-based sampling strategies for representing within-field nutrient levels. A site in the Red River Valley of North Dakota was observed over three years from 1994–1996. The site was divided into one field of continuous alfalfa (Medica sativa L.) and an adjacent field seeded to spring wheat (Triticum aestivum L.) in 1994, barley (Hordeum vulgare L.) in 1995 and alfalfa in 1996. Samples were taken from a 16.2-ha site each fall in a 33-m grid and analyzed for NO3-N, P, SO4-S and Cl. Topography was determined by measuring elevation in a 33-m grid with a laser-surveying device. Spatial dependence was determined by calculating the semivariogram and using regression analysis to assess the relationship between the semivariogram and the semivariogram model. Spatial dependence of NO3-N and P was strongest following spring wheat and barley, while spatial dependence for SO4-S and C1 was strongest for vigorous stands of alfalfa. When the continuous alfalfa stand declined following winter kill, NO3-N and P spatial dependence intensified. Topography based sampling was correlated with the 33-m grid by giving each 33-m sampling location its value as directed by a topography sampling, then correlating that topography based value with the original 33-m sampling value. Topography-based sampling was correlated with the 33-m sampling grid for all nutrients following spring wheat and barley, but not in continuous alfalfa until the stand began to decline in vigor. Following alfalfa seeding in the annual crop field, topography relationships with NO3-N and P decreased, while topography relationships with SO4-S and Cl increased. Topography samplings of sulfate-S and chloride were most highly correlated to 33-m grid values in vigorous alfalfa. Lack of NO3-N spatial dependence in the vigorous alfalfa stands suggests that a composite or field average soil test might be sufficient to provide soil NO3-N information under similar conditions.

[1]  B. A. Stewart,et al.  Nitrate-nitrogen Removal from Soil Profiles by Alfalfa 1 , 1975 .

[2]  L. N. Mielke,et al.  Relationship of landscape position and properties to crop production , 1989 .

[3]  Larry J. Smith,et al.  Nitrogen in sugarbeet tops and the growth of a subsequent wheat crop , 1996 .

[4]  C. V. Cole,et al.  AN EXPLORATORY METHOD FOR FRACTIONATION OF ORGANIC PHOSPHORUS FROM GRASSLAND SOILS , 1978 .

[5]  J. Blumenthal,et al.  Subsoil nitrate uptake and symbiotic dinitrogen fixation by alfalfa , 1996 .

[6]  J. L. Richardson,et al.  Evaporite Mineralogy and Groundwater Chemistry Associated with Saline Soils in Eastern North Dakota , 1987 .

[7]  W. E. Larson,et al.  RESIDUAL PHOSPHORUS AVAILABILITY IN LONG‐TIME ROTATIONS ON CALCAREOUS SOILS , 1954 .

[8]  S. Malhi,et al.  Changes in extractable phosphorus in Alberta soils during the fall-winter-spring interlude , 1992 .

[9]  D. K. Cassel,et al.  Soil-Landscape Relationships in a Closed Drainage System 1 , 1974 .

[10]  Relationship of Nitrogen and Topography , 1996 .

[11]  David W. Franzen,et al.  Field Soil Sampling Density for Variable Rate Fertilization , 1995 .

[12]  Doug Lenz Calculating Profitability of Grid Soil Sampling and Variable Rate Fertilizing for Sugar Beets , 1996 .

[13]  P. C. Robert,et al.  Spatial Relationships of Soil Nitrogen with Corn Yield Response to Applied Nitrogen , 1996 .

[14]  D. T. Lewis,et al.  Soil Properties Associated with Landscape Position , 1993 .

[15]  D. Cassel,et al.  Nitrogen-sulfur relationships in corn as affected by landscape attributes and tillage , 1996 .

[16]  R. McIver,et al.  EFFECTS OF TOPOGRAPHICAL POSITIONS, SOIL TEST VALUES, AND FERTILIZER USE ON YIELDS OF WHEAT IN A COMPLEX OF BLACK CHERNOZEMIC AND GLEYSOLIC SOILS , 1972 .

[17]  J. Sawyer Concepts of Variable Rate Technology with Considerations for Fertilizer Application , 1994 .

[18]  S. Malhi,et al.  Changes in extractable phosphorus between fall and spring in some Alberta soils , 1991 .

[19]  J. F. Dormaar SEASONAL PATTERN OF SOIL ORGANIC PHOSPHORUS , 1972 .

[20]  G. A. Nielsen,et al.  Farming Soils, Not Fields: A Strategy for Increasing Fertilizer Profitability , 1991 .

[21]  C. Gotway,et al.  Comparison of kriging and inverse-distance methods for mapping soil parameters , 1996 .

[22]  M. Clayton,et al.  Mapping Soil Test Phosphorus and Potassium for Variable‐Rate Fertilizer Application , 1994 .

[23]  Variability of Soil Nitrate and Phosphate Under Different Landscapes , 1996 .

[24]  Thomas S. Colvin,et al.  Spatiotemporal variability of corn and soybean yield , 1997 .

[25]  D. K. Barnes,et al.  Ineffectively and Effectively Nodulated Alfalfas Demonstrate Biology Nitrogen Fixation Continues with High Nitrogen Fertilization , 1995 .

[26]  D. Karlen,et al.  An evaluation of soil survey crop yield interpretations for two central Iowa farms , 1997 .

[27]  J. Zupancic,et al.  Determination of soil nitrate by transnitration of salicylic acid , 1990 .

[28]  J. L. Richardson,et al.  Pedogenic Carbonates in a Calciaquoll Associated with a Recharge Wetland , 1989 .

[29]  J. L. Richardson,et al.  Geochemistry of Hydric Soil Salinity in a Recharge-Throughflow-Discharge Prairie-Pothole Wetland System , 1989 .

[30]  D. R. Nielsen,et al.  Spatial variability of wheat yield and soil properties on complex hills , 1988 .