With advancements in corn hybrid genetics for excellent stress tolerance, farmers can plant corn at higher rates to achieve greater yields. The role of optimizing seed rates is important in maximizing corn yields. Below we’ll talk about the factors farmers must weigh when determining seed population rates.
What You Should Know
Optimal vs. Maximum Yield:
The production goal with every field is to achieve the correct seeding rate between an economically optimal yield and aiming for the maximum possible yield. The economic optimum seeding rate (when profitability is maximized) will always be slightly less than the seeding rate at which yield is maximized.
Seed Quality Matters:
We know only high-quality seed can produce a high-yielding harvest. It plays a significant role in determining the appropriate seeding rate. Seed germination percentage is a key indicator. When seed germination rates fall below 90%, it is often advised to compensate with a higher seeding rate. Our extensive range of tests surpass industry-required seed quality standards and each AgVenture independent seed company evaluates the results of these tests prior to selecting seed. Seed quality tests that are performed at AgVenture include cold germination or cold-saturated germination, which can provide a more realistic assessment of field performance.
Environmental Conditions:
The environment, including soil temperature and moisture levels, can significantly impact seed germination and seedling health. Planting in cooler or wetter conditions may necessitate higher seeding rates to mitigate the risks associated with suboptimal germination. Waiting until the soil temperature rises again might be better if a cool front moves in. The AgVenture brand Security Seed Protection System™ powered by LumiGEN® seed treatments for corn will also protect the elite genetics from early-season diseases, insects, and nematodes to help maximize yield potential with the given environment as well.
Hybrid Selection:
When it comes to seeding rates, there is no one-size-fits-all choice of corn hybrid. Different hybrids exhibit varying responses to seeding rates. Consult with your AgVenture Yield Specialist to align the genetics of your chosen hybrid from your local AgVenture independent seed company with an appropriate seeding rate strategy. Select germplasm locally selected to fit your unique growing conditions.
Action Steps
- Assess Seed Quality: Before determining the seeding rate, evaluate the quality of your corn seed. Ask your Seed germination percentages below 90% should prompt consideration of a higher seeding rate. Review your seed variety’s cold germination tests.
- Consider Environmental Factors: Be mindful of each field’s soil temperature and moisture conditions at planting. Adjust seeding rates for less-than-ideal germination conditions, such as potential cooling conditions immediately after planting.
- Consult your AgVenture Yield Specialist: Seek your agronomists’ expertise in the hybrids you plan to plant. Your agronomist’s insights can help you make informed decisions about seeding rates and your field’s economic optimum seeding rate. You can find your local AgVenture Yield Specialist by searching for your local AgVenture seed company here.
- Variable-Rate Seeding (VRS): While VRS technology allows for dynamic seeding rate adjustments within a field, its economic benefits may vary. Research suggests significant savings with VRS are challenging due to year-to-year variability and technology limitations.
Optimizing corn seeding rates is critical to achieving high yields and economic success in corn production. Balancing factors such as seed quality, environmental conditions, and hybrid selection is essential.
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References
Bullock, D.G., D.S. Bullock, E.D. Nafziger, T.A. Doerge, S.R. Paszkiewicz, P.R. Carter, and T.A. Peterson. 1998. “Does variable rate seeding of corn pay?” Agronomy Journal. 90:830-836.
Shanahan, J.F., T.A. Doerge, J.J. Johnson, and M.F. Vigil. 2004. “Feasibility of site-specific management of corn hybrids and plant densities in the Great Plains.” Precision Agriculture. 5(3):207-225.