REGENERATION FOCUSED. By carefully managing inputs, Mazeppa, Minn., strip-tiller Rod Sommerfield is hoping that one day he’ll be able to see 300 bushels of corn per acre and 100 bushels of soybeans per acre with 100% of the nitrogen and most of the other nutrients coming from natural sources due to his regenerative efforts.
One thing Mazeppa, Minn., strip-tiller and no-tiller Rod Sommerfield isn’t short on is ambition.
As a strong proponent of “regenerative agriculture,” his hopes for the future of the farm that’s been in his family since 1892 are bold. Rod and his son Rick now manage the farm, and they’ve zeroed in on a goal to ramp down inputs.
“Our long-term goal is to be producing 300 bushels of corn per acre and 100 bushels of soybeans per acre with 100% of the nitrogen (N) and most of the other nutrients coming from nature itself,” says Sommerfield.
He’s heard from experts at the University of Minnesota that it’s not possible, but Rod continues undeterred.
He cites studies by the university where surveyed fields showed about 43% of nutrients come from residue mineralization, 5-10% from atmospheric lightning, 8% from manure and 33% from the application of fertilizer.
“Their position is that you can’t manage or manipulate mineralization,” Rod says. “We’re totally on the opposite side of that. We’ve seen regenerative agriculture manage mineralization.”
Sommerfield has been banding fertilizer since 1972, and strip-till figures heavily into his regenerative practices. He feels that long-term conventional tillage around the country has created anaerobic soil environments that perpetuate themselves, and that the light touch of strip-till may be the perfect intermediary to return soils to their once rich state.
“Healthy soil function like lungs, exhausting spent biologic gases and taking in fresh oxygen,” says Sommerfield. “Tillage has always been a short-term fix of oxygen that mineralizes carbon and degrades soil structure. But without new organic matter soils become unable to breathe.
“Our long-term goal is to be producing 300 bushels of corn per acre and 100 bushels of soybeans per acre with 100% of the nitrogen (N) and most of the other nutrients coming from nature itself.” –Rod Sommerfield |
“The soil will then require more tillage to physically create pore space for root development, and for air and water to be held in the soil — in a sense becoming addicted to tillage. Strip-till is a great way to transition back to more natural practices.”
Sommerfield shared his experience-based practices, and some of the tenets of “regenerative agriculture” at the 2nd annual National Strip-Tillage Conference this past summer. Here are some takeaways.
1. Making a Residue Mix
Although continuous corn is an important facet of many farmers’ operations, Sommerfield feels that a two- or three-crop rotation is better suited to regenerating farm soils, noting his own corn-and-soybean rotation.
However, paying special attention to precisely how residue is managed and distributed is what ensures nutrients are available to crops when they need them.
“When harvesting corn, we leave as much of the stalk standing as possible by running the corn head close to the ear,” says Sommerfield. “In the spring, the ground will be drier and warmer for no-till or strip-tilled soybeans planted between the rows because less residue is on the ground.
“On our farm the stalks stand all the way until the following fall harvest. This way, when we harvest soybeans, the high-carbon stalks will go through the combine and blend with the soybean straw coming out of the chopper.”
Sommerfield says the residue mat left behind by the combine, being a natural blend of fresh and old residue, has almost a perfect carbon-to-nitrogen ratio for field composting.
“A lot of people say you can’t build soil during the soybean phase of a corn-soybean rotation, but we’ve seen just as much regeneration to the soils as we see on our corn phase,” says Sommerfield.
2. Managing P and K
Sommerfield says being vigilant of healthy mycorrhizal fungi populations in his soil has changed both where and how much added phosphorus (P) he applies.
“If there is a plentiful supply of phosphorus for a young corn plant during early development stages, the plant often will reject mycorrhizal fungi’s attempts to form a symbiotic relationship with it,” says Sommerfield. “We now try to limit phosphorus applied in the top 2-4 inches to no more than 16 pounds actual per acre. For this, we use liquid 10-34-0. Our main phosphorous dry fertilizer is 18-46-0 and we don’t put down more than 100 pounds per acre total.”
For potassium (K), not burying residue with conventional tillage again helps compound the nutrient conservation, he says. With more potassium available in the soil naturally, Sommerfield feels comfortable adding less.
“Strip-tilling keeps a lot of recycled potassium on the surface due to its high levels on the hard outer layers of decomposing crop residue,” says Sommerfield. “With what we do apply, strip-tilling potassium in a band helps keep it more available as it raises base saturation in the band area. This way, the soil deeper down is less likely to dry, which is important because potassium is only available when it’s soluble.”
On soybeans, he’ll apply up to 200 pounds per acre of 0-0-60, and on corn he’ll only go up to 100 pounds. In some of his closely watched test areas, though, he’s seen his regenerative practices pay off and he’s able to apply significantly less.
“The cover crops have helped with nutrient sequestration, too, but some of our management zones are getting around 300 bushels of corn per acre with only 150 pounds of applied nitrogen with only 16 pounds of phosphorus and no potassium,” says Sommerfield.
3. Testing Accurately
With the goal of continuing to dial down inputs, Sommerfield has to soil test very carefully to ensure an accurate assessment of what’s available to his crops. He suggests testing often, but with strip-till it’s also important where he tests.
“We see a tremendous root-mass increase with strip-till. We’ve dug plants in mid August that have gone down over 60 inches, which is great, but that means it’s pulling nutrients from deeper,” says Sommerfield. “We usually soil test every other year following soybeans, but now we take 12-inch samples where we used to only take 6-inch cores. Fertilizer is placed deeper and roots are obviously going down, so that’s where we need to test. We also individual test each one of our management zones.”
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