Subsurface drainage and subirrigation for increased corn production in riverbottom soils

Abstract Controlled subsurface drainage irrigation systems have been designed to promote agronomic production by optimizing water availability. In a previous manuscript we described the design of a 40 ha controlled subsurface drainage irrigation system, the soil resource and indicated the soil water properties. In this manuscript we describe the performance of corn (Zea mays L.) using a controlled subsurface drainage/irrigation system, with a focus on nutrient uptake at black layer formation. In a subsequent manuscript we will describe nutrient concentrations from tile drain effluents and note their potential impact on surface water resources. Crop yields using the controlled subsurface drainage/irrigation system substantially increased grain yields in 2008, 2011 and 2012 relative to previous corn production prior to the installation of the controlled subsurface drainage/irrigation system. Nutrient uptake (N, P, K, Ca, Mg, S, Fe, Mn, B, Cu, and Zn) was partitioned into leaf blades (blades), leaf sheaths (sheaths), culm (stem), tassel, ear leaves, shank, cob and grain. Nutrient concentrations in plant parts were estimated using plant tissue analysis, plant populations and dry matter production and expressed on a field basis (kg ha−1). The nutrient uptake by plant part at black layer showed that N, P, and S were more than 50% vested with grain. The remaining nutrients were primarily associated with the non-grain plant parts, especially K, Ca and B.

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Fertilizer and Swine Manure Management Systems: Impacts on Crop Production and Nitrate-Nitrogen Leaching with Subsurface Drainage

10.31274/farmprogressreports-180814-208 ◽

2003 ◽

Author(s):

Rameshwar S. Kanwar ◽

Carl H. Pederson ◽

James L. Baker ◽

Antonio P. Mallarino ◽

John E. Sawyer ◽

...

Keyword(s):

Crop Production ◽

Nitrate Nitrogen ◽

Swine Manure ◽

Subsurface Drainage ◽

Nitrogen Leaching ◽

Management Systems ◽

Manure Management

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Management of grape colaspis, Colaspis brunnea (Coleoptera: Chrysomelidae), in seed corn production

10.31274/rtd-180813-12169 ◽

2006 ◽

Cited By ~ 3

Author(s):

Benjamin Carl Kaeb

Keyword(s):

Corn Production ◽

Seed Corn

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Effects of Cover Crops and Tillage on Sweet Corn Production

HortScience ◽

10.21273/hortsci.33.3.476d ◽

1998 ◽

Vol 33 (3) ◽

pp. 476d-476

Author(s):

Gary R. Cline ◽

Anthony F. Silvernail

Keyword(s):

Cover Crops ◽

Sweet Corn ◽

N Fertilization ◽

Winter Rye ◽

No Tillage ◽

Corn Production ◽

Total N ◽

No Till ◽

Winter Cover ◽

Winter Cover Crops

A split-plot factorial experiment examined effects of tillage and winter cover crops on sweet corn in 1997. Main plots received tillage or no tillage. Cover crops consisted of hairy vetch, winter rye, or a mix, and N treatments consisted of plus or minus N fertilization. Following watermelon not receiving inorganic N, vetch, and mix cover cropsproduced total N yields of ≈90 kg/ha that were more than four times greater than those obtained with rye. However, vetch dry weight yields (2.7 mg/ha) were only about 60% of those obtained in previous years due to winter kill. Following rye winter cover crops, addition of ammonium nitrate to corn greatly increased (P < 0.05) corn yields and foliar N concentrations compared to treatments not receiving N. Following vetch, corn yields obtained in tilled treatments without N fertilization equaled those obtained with N fertilization. However, yields obtained from unfertilized no-till treatments were significantly (P < 0.05) lower than yields of N-fertilized treatments. Available soil N was significantly (P < 0.05) greater following vetch compared to rye after corn planting. No significant effects of tillage on sweet corn plant densities or yields were detected. It was concluded that no-tillage sweet corn was successful, and N fixed by vetch was able to sustain sweet corn production in tilled treatments but not in no-till treatments.In previous years normal, higher-yielding vetch cover crops were able to sustain sweet corn in both tilled and no-till treatments.

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Relationships between Phosphorus Levels in Soil and in Runoff from Corn Production Systems

Journal of Environmental Quality ◽

10.2134/jeq2003.0310 ◽

2003 ◽

Vol 32 (1) ◽

pp. 310 ◽

Cited By ~ 8

Author(s):

Todd W. Andraski ◽

Larry G. Bundy

Keyword(s):

Production Systems ◽

Corn Production ◽

Phosphorus Levels

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Effects and Economic Sustainability of Biochar Application on Corn Production in a Mediterranean Climate

Molecules ◽

10.3390/molecules26113313 ◽

2021 ◽

Vol 26 (11) ◽

pp. 3313

Author(s):

Juan Luis Aguirre ◽

María Teresa Martín ◽

Sergio González ◽

Manuel Peinado

Keyword(s):

Organic Carbon ◽

Mediterranean Climate ◽

Cost Savings ◽

Value Added ◽

Field Trials ◽

Economic Sustainability ◽

Corn Production ◽

Enhanced Production ◽

Wet Weight ◽

The Mediterranean

The effects of two types of biochar on corn production in the Mediterranean climate during the growing season were analyzed. The two types of biochar were obtained from pyrolysis of Pinus pinaster. B1 was fully pyrolyzed with 55.90% organic carbon, and B2 was medium pyrolyzed with 23.50% organic carbon. B1 and B2 were supplemented in the soil of 20 plots (1 m2) at a dose of 4 kg/m2. C1 and C2 (10 plots each) served as control plots. The plots were automatically irrigated and fertilizer was not applied. The B1-supplemented plots exhibited a significant 84.58% increase in dry corn production per square meter and a 93.16% increase in corn wet weight (p << 0.001). Corn production was no different between B2-supplemented, C1, and C2 plots (p > 0.01). The weight of cobs from B1-supplemented plots was 62.3%, which was significantly higher than that of cobs from C1 and C2 plots (p < 0.01). The grain weight increased significantly by 23% in B1-supplemented plots (p < 0.01) and there were no differences between B2-supplemented, C1, and C2 plots. At the end of the treatment, the soil of the B1-supplemented plots exhibited increased levels of sulfate, nitrate, magnesium, conductivity, and saturation percentage. Based on these results, the economic sustainability of this application in agriculture was studied at a standard price of €190 per ton of biochar. Amortization of this investment can be achieved in 5.52 years according to this cost. Considering the fertilizer cost savings of 50% and the water cost savings of 25%, the amortization can be achieved in 4.15 years. If the price of biochar could be reduced through the CO2 emission market at €30 per ton of non-emitted CO2, the amortization can be achieved in 2.80 years. Biochar markedly improves corn production in the Mediterranean climate. However, the amortization time must be further reduced, and enhanced production must be guaranteed over the years with long term field trials so that the product is marketable or other high value-added crops must be identified.

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