- Author: Jeannette E. Warnert
The Conservation Tillage workgroup has initiated a long-term study that directly compares the use of subsurface drip irrigation and overhead irrigation in a diverse no-till crop rotation. The drip lines are buried 10 to 12 inches deep, which will allow the scientists to experiment with a number of different crops over the next 6 or 7 years.
"We're trying to look at the flexibility of flat planting, diversity in cropping and drip irrigation, which is becoming the standard in many crops, and comparing this with overhead, automated mechanized irrigation," said workgroup chair Jeff Mitchell, UC Cooperative Extension cropping systems specialist. "We want to study what the future is going to be."
Currently, nearly all the Central California acreage of processing tomatoes is drip irrigated; cotton, in contrast, is still mostly grown with furrow irrigation. An increasing amount of acreage is also being irrigated with overhead, mechanized irrigation systems in recent years. In addition to cotton and tomatoes, the researchers plan to grow onions, broccoli and wheat on the plots.
Farmers visited the site of the new research during a workgroup meeting June 28 at the UC West Side Research and Extension Center near Five Points. At the first stop, the researchers introduced growers to conservation tillage research that compares no-till cotton and tomatoes planted in the residue of cover crops with crops grown using standard practices. These plots are furrow irrigated.
Data about soil surface water evaporation, soil temperature variances, nutrient differences, weed management, plant growth and yield are being collected.
In addition to generating data about the use of conservation tillage in California production systems, the CT workgroup encourages farmers to try conservation tillage in their own operations.
- Author: Jeannette E. Warnert
Workgroup member Ron Harben, air quality planner and coordinator with the California Association of Resource Conservation Districts, asked the congressman for $5 million over five years to study the adoption process and fund CT extension activities.
Harben suggested U.S. representatives create a California agriculture caucus in order to work together to ensure the state, the No. 1 ag producer in the nation, gets its fair share of federal support for agricultural programs.
Costa said he liked the idea of establishing a California ag caucus.
"The question is how to put it together without it becoming political," he said. "We had such a caucus with 21 bipartisan members. It worked pretty well for a number of years."
Congressman Jim Costa comments about conservation tillage in this 90-second video.
- Author: Jeannette E. Warnert
UC Davis cropping systems specialist Jeff Mitchell appeared a Fresno morning ag show on KMJ 580 am radio. The radio story is archived online, about midway through the hour-long broadcast.
Mitchell conducted a phone interview with host Sean Michael Lisle in which he said national experts on no-till and strip-till came to California to encourage the state's farmers to try conservation tillage, which can conserve water, suppress dust, reduce runoff, lower labor costs, save fuel and sequester carbon.
"There is a growing interest now in these kinds of systems that potentially can reduce production costs and can have a number of adjunct benefits associated with them, and that would be quite new for California," Mitchell said on the program. "Currently in California, very little of the annual crops, row crops, field crops are grown with these kinds of practices."
Mitchell said the dairy industry has been particularly receptive to the idea.
"Our workgroup has documented some rather significant changes in tillage practices in the last 6 years," Mitchell said. "The adoption of these kinds of practices has actually gone up to about 20 percent of the acreage from about 2 percent in that time period."
- Posted By: Jeannette E. Warnert
- Written by: Jeff Mitchell
Cover crops, or vegetation that was grown after the cash crop was harvested, was a practice that was widely used in the 1940s and 1950s. The vegetation was used to maintain or increase the fertility of the soil before commercial fertilizers became widely available. The cover crops also provided organic matter to the soil that was necessary to keep the soil easy to plow. When commercial fertilizers became more widely used, cover crops faded from the agricultural picture.
Cover crops are making a comeback of sorts due to the depletion of the organic matter over the intervening decades of intense farming as well as farmers taking advantage of a cover crop’s environmental benefits. A winter cover crop can add back to the soil the organic matter that was lost due to farming practices as well as take up the fertilizer left over from the previous crop that can potentially leach into the ground water or runoff in storm water. A well-managed cover crop can also provide needed protection from raindrop impact that can cause a crust to form on the surface of the soil that further reduces water penetration and adequate air movement through the soil. The vegetation can also keep soil moisture from evaporating when young crops need it most.
To help farmers learn more about the “lost art of cover cropping” and to see actual cover crop management techniques up close and personal, the University of California’s Conservation Tillage and Cropping Systems Workgroup conducted an interactive field day on March 18 at the West Side Research and Extension Center in Five Points, Calif. The session came on the heels of a three-day conference series the previous week that provided examples of successful high-residue cropping systems that also use cover crops from other irrigated regions of the U.S.
The backdrop for the field day was a field that has been comparing no-till cotton and tomato production techniques for the last eight years. Comparisons between crops grown with and without winter cover crops have been measured against current standard “clean cultivation” management in which no cover crop is used. Also compared was a standard tillage system in which winter cover crops are “green manured” or incorporated into the soil in the spring before the next crop is planted.
UC Davis researcher, Jeff Mitchell, reported that about two tons of cover crop dry matter - of which roughly 40 percent is carbon and 2 percent is nitrogen - has been produced in the cover crop plots each year with winter rainfall and no supplemental irrigation. These cover crops resulted in a 22 percent increase in soil carbon in the green manured, standard tillage system, and an even higher 29 percent increase in soil C in the no-till cover crop system following the eight years of study.
From year to year, the water available for agriculture can vary greatly so cover crops must be able to “work their magic” with little or no increased water requirements. Because wintertime temperatures are lower and the humidity is generally higher, evapotranspiration (ET) - or the water that both evaporates from the soil and water that is used by plants - during the winter growing period tends to be much lower than in summer. However, a winter-growing cover crop is using water that would normally be available to a spring-planted crop. Therefore, farmers need to weigh the many advantages of a cover crop with the potential disadvantage of its winter water use.
Mitchell’s monitoring of the top foot of soil three days before the field day indicated about 3 inches of water in the fallow plots with only about 2.5 inches in the cover crop plots. The cover crop that Mitchell used this year consisted of Tillage Radish™, forage pea, and Phacelia, and had produced about 7,000 pounds of dry matter per acre at the time of the field day.
The field day also featured Greg Wittenborn of Lockwood Seed and Grain of Chowchilla, Calif., and Chuck Cambra and Tom Johnson of Kamprath Seed in Manteca, Calif. The trio provided information on cover crop seed costs, the importance of selecting cover crop materials, and designing cover crop strategies to achieve specific cropping goals. Many cover crop species and mixes are now commercially available to address a farmer’s specific needs.
Additional information on cover crops will be posted at the Workgroup’s website http://ucanr.org/sites/ct/ and opportunities for viewing other field operations related to cover cropping will be publicized via the Workgroup’s email announcement service. To become involved with the Conservation Tillage and Cropping Systems Workgroup, contact workgroup chair Jeff Mitchell at mitchell@uckac.edu.
Two of the methods for terminating cover crops that were demonstrated at the cover crop field day in Five Points, Calif. On the left is a conventional flail mower that flail chops standing cover crop materials leaving very small pieces of shredded above-ground material. On the right is a cover crop stalk chopper that is ground-driven and chops standing cover crops leaving 7- to 8-inch pieces of above-ground matter. (Photo by Ron Harben.)
Chuck Cambra of Kamprath Seed Company in Manteca, Calif., (in gray sweatshirt at center-left of photo) addressing participants of the cover crop field day held in Five Points, Calif., on March 18. (Photo by Ron Harben.)
- Author: Jeannette E. Warnert
Whether it’s called “high residue farming” or “conservation agriculture,” there’s very little of it currently done in California. For decades, the dominant production paradigm throughout California has been just the opposite - intense tillage, clean cultivation and residue-free fields.
There is, however, growing interest in these sorts of crop production alternatives as evidenced by the lively and engaging discussions that took place as part of the recent three-day conference series, "New horizons for conservation cropping in California," March 9, 10 and 11 in Davis, Tulare and Five Points, respectively. The events brought three leaders in the development of high residue conservation tillage systems under irrigated conditions to California’s Central Valley to share their experiences and to propose possible applications of these cropping approaches for California farmers.
Mike Petersen, precision tillage agronomist with Orthman Mfg. and former USDA Natural Resources Conservation Service Area soil conservationist for the 18 northeastern counties of Colorado, presented an extensive research base that he has helped develop demonstrating advantages of precise fertilizer placement at two depths below the seed, leading not only to increased early season root growth, but also grain yield for strip-till corn versus conventionally tilled corn.
By only tilling in the areas of the field where seed is sown, typically about 30 percent or less of the total soil area, less than about two gallons of diesel fuel are used, little or no soil erosion occurs, and yield increases averaging 11 to 30 bushels per acre have been seed over an eight-year field comparison. Precision tillage and fertilizer placement that are readily afforded by strip-tillage planting systems would thus have considerable and multiple advantages that may have clear relevance for California producers.
Since 2004, Andy McGuire, educator with Washington State University based in Moses Lake, Wash., has been working with Central Washington farmers to develop successful high residue systems for a variety of the region’s diverse irrigated crops. He has found that there tends to be typically no single factor motivating farmers to adopt high residue production techniques, but rather a suite of reasons that often combine to influence crop management decisions.
Compared to conventional systems, high residue farming systems involve less overall tillage, diesel fuel use and labor, opportunities for double-cropping, and more free time, as well as reduced soil water evaporation. Essentially, all of the quite diverse crop production in this region of Washington relies on overhead center pivot irrigation, which McGuire pointed out is particularly well suited for high residue farming because furrows and beds do not need to be prepared to move water across a field as is done with surface irrigation.
High residue cropping opportunities that Washington farmers are now using that may have relevance for California include edible dry beans strip-till planted into alfalfa, strip-till seeded onions into burned down wheat cover crop residue for wind protection, and even potato production systems that reduce wind erosion by preserving surface residues of prior crops.
The progress and accomplishments of Dwayne Beck, the final presenter at the “New Horizons for Conservation Cropping in California” conferences, and the farmers in central South Dakota he has been working with since the 1980s are in many fundamental ways nothing short of phenomenal and transformative, and provided considerable “food for thought” for the California farmers, researchers, and consultants who participated in each of the three conference sessions.
Beck is the South Dakota State University manager of the Dakota Lakes Research Farm, a farmer-owned research facility just outside the state’s capital of Pierre that has been no-till farmed since 1990. The no-till, high residue systems developed by Beck and his farmer colleagues have resulted in reduced soil water evaporation, far greater cropping diversification and intensification, considerably lower pesticide inputs, and increased net farm income throughout the region by over a billion dollars since the early 1990s.
Tillage, Beck pointed out, reduces the ability to manage the overall crop production system and should be replaced by other cultural practices including surface residue conservation, rotation, sanitation and competition. The benefits of no-till high residue systems will eventually have relevance for California as well, Beck suggested, and farmers here should also be able to “take the E out of ET” as their counterparts in South Dakota have done, once they “take the T out of ‘can’t.’”