Dryland Corn and Grain Sorghum Yield Response to Available Soil Water at Planting

Schlegel, Alan J.; Lamm, Freddie R.; Assefa, Yared; Stone, L. R.

doi:10.2134/agronj2017.07.0398

Cited by 19 publications

(21 citation statements)

References 39 publications

(47 reference statements)

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“…Reduced heat stress and enhanced soil water availability due to above-average precipitation may have increased grain yield in these years. Dryland corn grain yield responds linearly to available soil water from precipitation and irrigation (Nielsen et al, 2010;Schlegel et al, 2018). Increased grain yield compared with biomass increased harvest index in 2006, 2009, and 2010 when air temperature and precipitation were favorable for corn growth compared with other years.…”

Section: Tillage System †mentioning

confidence: 99%

Dryland Corn Production and Water Use Affected by Tillage and Crop Management Intensity

et al. 2018

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Management strategies to enhance dryland corn (Zea mays L.) production and soil water use are lacking. We evaluated the effect of tillage and crop management intensity on the growth, yield, and water use of dryland corn from 2005 to 2010 in the northern Great Plains. Tillage systems (no-tillage, NT, and conventional tillage, CT) as main-plot and crop management to corn (traditional intensity: conventional seeding rates and reduced wheat, Triticum aestivumL., stubble height; and improved intensity: increased seeding rate for 3 out of 6 yr and wheat stubble height) as split-plot treatments were arranged in a randomized complete block design with three replications. Corn plant stand was greater for CT than NT in 3 out of 6 yr and greater for the improved than the traditional intensity in 3 out of 3 yr. Seed number and grain yield were greater for NT than CT in 4 out of 6 yr. Biomass was greater for NT than CT in 1 out of 6 yr and greater for NT than CT in the traditional intensity. Corn plant height, seed weight, and harvest index as well as preplant and postharvest soil water, water use, and water-use efficiency were not influenced by treatments, but varied with years. Corn yield increased for NT compared with CT during years with below-average precipitation due to increased seed number and by reducing seeding rate and wheat stubble height. No-tillage with reduced seeding rate and wheat stubble height can enhance dryland corn production without affecting soil water. Disciplines

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Section: Tillage System †mentioning

confidence: 99%

Dryland Corn Production and Water Use Affected by Tillage and Crop Management Intensity

et al. 2018

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“…The fallow phase of the production system is critical for conservation of soil water that stabilizes wheat yields and prevents crop failure in drier years in NT regions of the semiarid Great Plains (Haas et al 1974;Nielsen and Vigil 2010). In this water-limited environment, crop yields are directly related to available soil moisture at time of cash crop seeding (Schlegel et al 2018). Despite the weed-suppression benefits of CCs, previous research demonstrated that replacing fallow with CCs often resulted in decreased soil water content at time of cash crop seeding (Holman et al 2018;Nielsen and Vigil 2018;Schlegel and Havlin 1997;Unger and Vigil 1998;Zentner et al 1996).…”

Section: Soil Moisture Trade-offs and Impacts On Cash Crop Yieldsmentioning

confidence: 99%

“…), and chick pea (Cicer arietinum L.) have replaced a portion of this fallow period in the northern parts (Miller et al 2003). Similarly, several new crops have been evaluated in 3-or 4-yr rotation schemes by including cereal crops (Nielsen and Vigil 2018;Schlegel et al 2018), legumes as forage and grain crops (Holman et al 2018;Lyon et al 2004), and recently oilseed crops (Obour et al 2018) for potential replacement of fallow in the Central Great Plains (Figure 1). Despite these efforts to increase cropping intensity, crop rotations in the region still include a fallow phase, and most growers practice fallow as a strategy to minimize risk of drought and crop failure.…”

Section: Introductionmentioning

confidence: 99%

Integrating cover crops for weed management in the semiarid U.S. Great Plains: opportunities and challenges

et al. 2020

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The widespread evolution of herbicide resistance in weed populations has become an increasing concern for no-tillage (NT) growers in semiarid regions of the U.S. Great Plains. Lack of cost-effective and alternative new herbicide sites of action further exacerbates the problem of herbicide-resistant (HR) weeds and threatens the long-term sustainability of prevailing cropping systems in the region. A recent decline in commodity prices and increasing herbicide costs to manage HR weeds has spurred research efforts to build a strong rationale for developing ecologically based integrated weed management (IWM) strategies in the U.S. Great Plains. Integration of cover crops (CCs) in NT dryland production systems potentially offers several ecosystem services, including weed control, soil health improvement, decline in selective pest pressure, and overall reduction in pest management inputs. This review article aims to document the role of CCs for IWM, with emphasis on exploring emerging weed issues; ecological, economic, and agronomic benefits of growing CCs; and constraints preventing adoption of CCs in NT cropping systems in the semiarid Great Plains. We attempt to focus on changes in weed management practices, their long-term impacts on weed seedbanks, weed shifts, and herbicide-resistance evolution in the most common weed species in the region. We also highlight current knowledge gaps and propose new research priorities based on an improved understanding of CC management strategies that will ultimately aid in achieving sustainable weed management goals and preserving natural resources in water-limited environments.

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“…Bushong et al reported the impact of preplant irrigation on phosphorus and potassium fertilizer management in winter wheat with grain yield and water productivity optimized under preplant irrigation condition [35]. Schlegel et al found an increase in rainfed maize grain yield from 27 to 33 kg/ha/mm of pre-plant irrigation when in-season precipitation ranged from 196 to 215 mm and yield decrease from 9 to 25 kg/ha/mm when the in-season precipitation ranged from 288 to 354 mm under increasing preplant irrigation amounts (0, 38, 76, or 114 mm) at two locations in Kansas [36]. Rainfed grain sorghum yield also increased with increasing preplant irrigation amounts from 12 to 22 kg/ha/mm and from 0 to 6 kg/ha/ mm under in-season precipitation ranges of 163 -281 mm and 315 -382 mm respectively [36].…”

Section: Effect Of Preplant Irrigation On Crop Yields and Water Use Ementioning

confidence: 99%

“…Schlegel et al found an increase in rainfed maize grain yield from 27 to 33 kg/ha/mm of pre-plant irrigation when in-season precipitation ranged from 196 to 215 mm and yield decrease from 9 to 25 kg/ha/mm when the in-season precipitation ranged from 288 to 354 mm under increasing preplant irrigation amounts (0, 38, 76, or 114 mm) at two locations in Kansas [36]. Rainfed grain sorghum yield also increased with increasing preplant irrigation amounts from 12 to 22 kg/ha/mm and from 0 to 6 kg/ha/ mm under in-season precipitation ranges of 163 -281 mm and 315 -382 mm respectively [36]. Stone, et al investigated the timing of off-season irrigation in maize in Kansas and found that offseason irrigation timing did not significantly impact maize yield and concluded that off-season irrigation of maize was not a water efficient practice [20].…”

Section: Effect Of Preplant Irrigation On Crop Yields and Water Use Ementioning

confidence: 99%

Preplant Irrigation Effectiveness and Crop Yield and Water Productivity in the United States: A Review

2019

JAHR

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Soil moisture content early growing season is determinant for crop season planning mainly a decision on planting date. In the region where off season or early season precipitation does not much the conditions for seed germination and plant growth/ development, preplant irrigation is applied to meet these conditions. Also, under limited water availability or low system capacity to meet crop water requirement at peak evapotranspiration, preplant irrigation could be applied to store water within the crop root zone. However, its efficiency or effectiveness depends on the soil type and soil water storage efficiency. This review explored the advantages and disadvantages of the practice and its impact on crop yield and water productivity using summaries of different researches conducted mostly in the United States and other regions. The consideration of applying preplant irrigation should be examined regarding soil type, crop management practices, tillage and residue management, irrigation technique, actual precipitation pattern and forecast, crop choice to optimize the preplant irrigation practice for system sustainability.

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Dryland Corn and Grain Sorghum Yield Response to Available Soil Water at Planting

Cited by 19 publications

References 39 publications

Dryland Corn Production and Water Use Affected by Tillage and Crop Management Intensity

Dryland Corn Production and Water Use Affected by Tillage and Crop Management Intensity

Integrating cover crops for weed management in the semiarid U.S. Great Plains: opportunities and challenges

Preplant Irrigation Effectiveness and Crop Yield and Water Productivity in the United States: A Review

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