Water Conservation in Driest Area

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Water Conservation in Driest Area

In the World's Driest Rainfed Wheat Region, Washington State University Researchers Have Identified Summer Fallow Management Practices that Can Make all the Difference for Farmers, Water and Soil Conservation, and Air Quality

In the world's driest rainfed wheat region, Washington State University researchers have identified summer fallow management practices that can make all the difference for farmers, water and soil conservation, and air quality.

Wheat growers in the Horse Heaven Hills of south-central Washington farm with an average of 6-8 inches of rain a year. Wind erosion has caused blowing dust that exceeded federal air quality standards 20 times in the past 10 years.

"Some of these events caused complete brown outs, zero visibility, closed freeways," said WSU research agronomist Bill Schillinger.

Science to anchor farmer incentives

He and WSU agricultural economist Doug Young compared three fallow management systems in the western part of the Horse Heaven Hills with six inches of annual rainfall and the same practices in the eastern part with eight inches of rain.

The study was published in the Soil Science Society of America Journal .

The five-year study provides the U.S. Department of Agriculture's Natural Resources Conservation Service with science-based information needed to develop incentives forwheatfarmers to change from traditional-tillage fallow practices to undercutter-tillage or no-till fallow systems.

Timing to trap moisture

Farmers in the Horse Heaven Hills practice a winter wheat-summer fallow rotation where only one crop is grown every other year on a given piece of land.

Average yields can be as low as 18 bushels per acre - compared to upwards of 120 bushels per acre in the higher rainfall area of the Palouse in eastern Washington. Though the margins are tight, with careful management wheat farming in the Horse Heaven Hills can be profitable.

To get the highest yield, farmers need to plant winter wheat in late August or early September after a year of fallow. The fallow period allows enough moisture from winter and spring rains to accumulate in the soil for seeds to get established.

"In east-central Washington, if you can't plant in late summer into deep seed-zone moisture in fallow, then you have to wait for fall rains in mid-October or later," Schillinger said.

The longer it takes to get winter wheat seedlings established, the lower the potential for good yields.

To help ensure precioussoil moistureremains in the seeding zone, farmers till the soil in the spring. Tillage breaks up the capillary action of the soil; this helps slow soil moisture evaporation in the seed zone during the hot, dry summer months.

But too much tillage can cause soil loss through wind erosion that feeds hazardous dust storms.

Undercutting in the east

Compared to traditional tillage, Schillinger and Young found that undercutter tillage was the best option for fallow in the slightly moister eastern region of the Horse Heaven Hills, where late-August planting is possible and spring tillage helps retain summer soil moisture.

With wide, narrow-pitched, V-shaped blades, the undercutter slices beneath the soil surface to interrupt capillary action in the seed zone without causing much disturbance of the soil surface.

Schillinger said scientists and farmers have conclusively shown that spring tillage with the undercutter effectively retains seed-zone moisture. It also retains significantly greater surface residue and surface soil clods - which are less likely to be disturbed by wind and become airborne - compared to traditional tillage implements such as a tandem disk or field cultivator.

Source: Phys.org

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