Growing maize in clumps as a strategy for marginal climatic conditions

Abstract Under dryland conditions of the Texas High Plains, maize ( Zea mays ) production is limited by sparse and erratic precipitation that results in severe water stress particularly during grain formation. When plant populations are reduced to 2.0–3.0 plants m −2 to conserve soil water for use during grain filling, tillers often form during the vegetative growth and negate the expected economic benefit. We hypothesized that growing maize in clumps spaced 1.0 m apart would reduce tiller formation, increase mutual shading among the plants, and conserve soil water for grain filling that would result in higher grain yield. Studies were conducted during 2006 and 2007 at Bushland, TX. with two planting geometries (clump vs. equidistant), two irrigation methods (low-energy precision applicator, LEPA, and low-elevation spray applicator, LESA) at three irrigation levels (dryland, 75 mm and 125 mm in 2006; and dryland, 50 mm and 100 mm in 2007). For dryland plots in 2007, clump plants had only 0.17 tillers (0.66 tillers m −2 ) compared with 1.56 tillers per plant (6.08 tillers m −2 ) for equidistant spacing. Tillers accounted for 10% of the stover for the equidistant plants, but less than 3% of the grain. Clump planting produced significantly greater grain yields (321 g m −2 vs. 225 g m −2 and 454 g m −2 vs. 292 g m −2 during 2006 and 2007, respectively) and Harvest Indexes (0.54 vs. 0.49 and 0.52 vs. 0.39 during 2006 and 2007, respectively) compared with equidistant plants in dryland conditions. Water use efficiency (WUE) measurements in 2007 indicated that clumps had a lower evapotranspiration (ET) threshold for initiating grain production, but the production function slopes were 2.5 kg m −3 for equidistant treatments compared to 2.0 kg m −3 for clump treatments. There was no yield difference for method of irrigation on water use efficiency. Our results suggest that growing maize in clumps compared with equidistant spacing reduced the number of tillers, early vegetative growth, and Leaf Area Index (LAI) so that more soil water was available during the grain filling stage. This may be a useful strategy for growing maize with low plant populations in dryland areas where severe water stress is common.

[1]  S. Prihar,et al.  Using upper-bound slope through origin to estimate genetic harvest index. , 1990 .

[2]  G. Hammer,et al.  The effect of row configuration on yield reliability in grain sorghum: I. Yield, water use efficiency and soil water extraction , 2003 .

[3]  P. Unger Conversion of Conservation Reserve Program (CRP) Grassland for Dryland Crops in a Semiarid Region , 1999 .

[4]  J. T. Musick,et al.  Long-Term Irrigation Trends – Texas High Plains , 1990 .

[5]  W. Stroup,et al.  Optimal Plant Population and Nitrogen Fertility for Dryland Corn in Western Nebraska , 2003 .

[6]  T. A. Howell,et al.  LEPA AND SPRAY IRRIGATION OF CORN—SOUTHERN HIGH PLAINS , 1998 .

[7]  J. Casal,et al.  The effect of plant density on tillering: The involvement of R/FR ratio and the proportion of radiation intercepted per plant , 1986 .

[8]  C. Norwood Planting Date, Hybrid Maturity, and Plant Population Effects on Soil Water Depletion, Water Use, and Yield of Dryland Corn , 2001 .

[9]  S. Idso,et al.  Canopy temperature as a crop water stress indicator , 1981 .

[10]  B. Stewart,et al.  Growing dryland grain sorghum in clumps to reduce vegetative growth and increase yield , 2006 .

[11]  Terry A. Howell,et al.  Yield and Water Use Efficiency of Corn in Response to LEPA Irrigation , 1995 .

[12]  Terry A. Howell,et al.  Seasonal and maximum daily evapotranspiration of irrigated winter wheat, sorghum, and corn : Southern High Plains , 1997 .

[13]  B. A. Stewart,et al.  Grain Sorghum Tiller Production in Clump and Uniform Planting Geometries , 2009 .

[14]  R. Aiken,et al.  Skip‐Row Planting Patterns Stabilize Corn Grain Yields in the Central Great Plains , 2009 .

[15]  Paul D. Colaizzi,et al.  Comparison of SDI, LEPA, and spray irrigation performance for grain sorghum , 2004 .

[16]  Terry A. Howell,et al.  Evapotranspiration and Growth Predictions of CERES Maize, Sorghum and Wheat in the Southern High Plains , 1991 .

[17]  A. G. Cirilo,et al.  Yield Responses to Narrow Rows Depend on Increased Radiation Interception , 2002 .

[18]  O. Babalola,et al.  Effects of Planting Patterns and Population on Water Relations of Maize , 1981, Experimental Agriculture.

[19]  D. J. Flower,et al.  Effect of Heat and Drought Stress on Sorghum (Sorghum Bicolor). I. Panicle Development and Leaf Appearance , 1993, Experimental Agriculture.

[20]  P. Unger Paper Pellets as a Mulch for Dryland Grain Sorghum Production , 2001 .

[21]  W. D. Shrader,et al.  Grain Yields, Evapotranspiration, and Water Use Efficiency of Grain Sorghum under Different Cultural Practices1 , 1959 .

[22]  C. H. M. van Bavel,et al.  Water Loss from a Sorghum Field and Stomatal Control1 , 1968 .

[23]  C. V. Bavel,et al.  Soil Surface Water Depletion and Leaf Temperature1 , 1972 .

[24]  S. Idso,et al.  Wheat canopy temperature: A practical tool for evaluating water requirements , 1977 .

[25]  Freddie R. Lamm,et al.  Water Requirement of Subsurface Drip-irrigated Corn in Northwest Kansas , 1995 .