Knowing Your Roots

Archive for the ‘Water/High-Capcity Wells’ Category

Working Together – Stakeholders Unite to Protect Our Water through the Little Plover Conservancy Project

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The farm fields are coming to life in Wisconsin’s Central Sands as the potato, sweet corn, green bean and pea crops — the lifeblood of Portage County’s bountiful agriculture — come into blossom.  As we watch and enjoy this remarkable productivity unfold, it’s a good time to reflect on what makes it all possible. The Sands themselves and the underlying groundwater aquifer created in the glacial ages are the foundation. Maintaining the delicate balance between these precious natural resources and the needs of everyone who uses and depends on them, is an ongoing challenge that we all must be a part of if future generations are to enjoy the benefits of this unique area.

Nowhere is this challenge more daunting than in the Little Plover River watershed in northern Portage County. The Little Plover is a trout stream that meanders its way westward from its headwaters east of the ancient Johnstown glacial moraine through wetlands, woods, farmland, and the homes, parks, businesses, and industries of the bustling village of Plover to its confluence at the Wisconsin River south of Stevens Point. In recent years, the Little Plover has experienced fluctuations in its flow patterns that include reduced flows in late summer and even areas that have dried up altogether in extremely dry years.

The future sustainability of this watershed is important and everyone who lives in the area or depends on its water needs to come together and work to implement strategies that will contribute to securing the resource for generations to come.

It is exciting to report that this is already coming to fruition through the foresight of a group of individuals and organizations who are working together to implement  far-reaching plans address water issues in the watershed through the Little Plover River Conservancy Project. The collaboration brings together the Village of Plover, Wisconsin Potato and Vegetable Growers Association (WPVGA) and its member growers, the Department of Natural Resources (DNR), and the Department of Transportation. The Little Plover Conservancy is an ambitious and multi-faceted approach, which involves:

  • The Village of Plover secured a state grant from the Wisconsin Department of Natural Resources and Portage County (Land Preservation Fund) to create a conservancy park.
  • This is the first step in a broader master plan, which will create hunting, fishing, trapping, hiking and cross-country skiing in concert with an educational mission. This in addition to the 19 parks already established in the village! The DNR also funded a major research project being conducted by the Wisconsin Geological and Natural History Survey to model groundwater in the watershed and help identify ways to improve stream flows.

The resources and energy being invested in this relatively small watershed are indeed impressive, and they reflect the commitment of everyone in the area to work together to protect these assets on which we all depend.

 

 

 

Vegetable Growers Pushing Advanced Irrigation and Conservation Practices in Wisconsin

We need to conserve our natural resources to guarantee that they will be there for future generations!  We all work to conserve — in our own homes, work places, towns and communities — and we expect our industries to do the same.  Irrigated vegetable growers in Central Wisconsin agree and their highest priority is to conserve the water that they rely on to irrigate the crops that supply food to our tables!  Below are some comments taken directly from growers in Central Wisconsin that reflect that commitment.  Since water conservation is essential for the long term sustainability of the vegetable industry, growers are working to use advanced technologies and best management approaches directly on their farms to maintain these resources.

“Water conservation is important to our farm because we believe in promoting a sustainable environment; both for our farm as a whole and for the community around us.”

“The more water we conserve now the higher availability in the future.”

“Water conservation is important so we don’t …waste ground water which everyone depends upon.”

“We need to be stewards of the resources so we can continue for generations to come.”

“Sustainability is always an important goal on a family farm!”   (more…)

Using Less Water to Grow More Food

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Wisconsin’s Central Sands is a unique and bountiful place. Its rain-fed groundwater aquifer feeds one of the nation’s most productive potato and vegetable growing areas. The sandy glacial soils and easily accessible aquifer for irrigation allow Wisconsin to rank in the top three in green beans, peas, sweetcorn and potatoes, which contribute to our diverse and healthy agricultural economy. With an average annual rainfall of 32”, our aquifer is replenished yearly and the groundwater level remains constant, with minor fluctuations.

Ever mindful of the importance of a sustainable groundwater supply and how this resource has been depleted in other parts of the country, potato growers recently measured the depth to groundwater in over 50 irrigation wells in Portage county and found that all but 3 have groundwater at the same or higher levels compared to those recorded when they were first drilled over the last half century. This careful scrutiny is being expanded across the 6-county sands area to ensure that our groundwater is not at risk.

This same aquifer is also connected to and essential for the well-being of the many streams, lakes and wetlands that make the sands an ideal place to live. Wisconsin potato growers are at the forefront in managing these fragile ecosystems, and making sure they remain healthy during dry climate years, when the need for agricultural water use increases. The potato industry is sensitive to these concerns and is actively seeking new ways to irrigate their crops using less water. One logical approach is to increase productivity so that more food can be grown on fewer acres. Potatoes are a good example where this has been achieved. Over the past decade, innovations in production gained through improvements in varieties, fertility, soil health and pest management have allowed growers to produce 95% of the potatoes they did a decade ago but on 20% fewer acres, saving a whopping 25% of the water needed to grow potatoes!

Growers are now actively working with UW researchers to reduce water use still further. In the Department of Horticulture, a research group led by Mike Drilias, is looking at ways to induce crops to root deeper and use the water in the soil more efficiently. One method currently being studied is to simply apply less water to the crop (deficit irrigation) throughout the growing season and force the roots go deeper to find it. Mike has found that crops respond differently to such treatment. Potatoes differ by variety with some less affected while other varieties lose yield and, surprisingly, sweetcorn attained the same yields with 25% less water. Withholding water at specific growth stages (deferred irrigation) is another approach that is rapidly gaining acceptance by growers. Naturally deep-rooted crops such as soybeans, field corn and sweet corn, tend to ‘cheat’ when water is plentiful near the surface and develop shallow root systems but when water is withheld early in the season roots will go deeper and use water that would otherwise be lost. Such tactics can save growers over 2 inches of water on an acre of cropland—that’s 7 million gallons on a single field—without sacrificing yield.

An exciting new concept is also now being investigated that could prove critical in conserving water in irrigated agricultural systems. This takes advantage of the differential use of water by crops, which has been studied by UW departments of Horticulture, Soils, Agronomy and Biological Systems Engineering faculty and students. This differing need for water among crops opens the potential for designing future agricultural landscapes that can be profitable and yet use less water. Such landscapes have been evolving naturally, driven by economic and production considerations over the past 20 years. As potato acreage, (which requires 18 to 22 inches of total water throughout the growing season, including rainfall), has declined in response to greater productivity, the acreages of green beans (which need only 6.5 inches) and sweet corn (needing 12 inches) have increased to fill the gap, resulting in landscapes that actually use 25% less water. The potato and vegetable industry is actively supporting research in this area with the goal of designing landscape strategies to develop crop rotations in space and time to promote water conserving farmscapes.

For more information contact: wyman@ wisc.edu

Drip Irrigation: Doing More with Less

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Most people are already familiar with drip irrigation—they’ve used soaker hoses in the garden or seen those thin tubes in greenhouses or even in orchards. However, on large-scale agricultural lands within Wisconsin, drip irrigation is rarely seen.  Since water is usually plentiful in the state, irrigation is delivered to crops with overhead sprinklers, traveling water guns or with rotating center pivot systems. This doesn’t happen in areas where water supplies are scarce.  In other grower regions – either in the U.S. or worldwide – growers use watering systems that can be controlled to only deliver the exact amount of water the plants need, via the system known as drip irrigation.

Drip irrigation was first used commercially in Israel in the mid-1900s when the advent of plastics made it possible. It continues to be a dominant form of irrigation in many arid (dry) regions where water is the most limiting factor in crop production. In the U.S., drip irrigation is found predominantly in dry agricultural regions, such as California and Florida, where hundreds of thousands of acres of high-value crops are produced using drip irrigation.  Historically, drip irrigation had been primarily used with permanent tree and vine plantings, but new research and applications have made it increasingly desirable for specialty crops, vegetables and even row crops like cotton and corn.

In Wisconsin, less than 1% of the 500,000 irrigated acres use drip irrigation (under surface drip, subsurface, trickle or other forms of micro irrigation) and much of this acreage is in small-scale vegetable production. Wisconsin growers may not face the level of water scarcity seen in the western part of the country, but as concerns over groundwater quality and quantity increase, it may be necessary to explore alternative production strategies.

Drip irrigation has been shown to allow for significant reductions in water and nutrients by better localizing applications in the crop root zone where they can be delivered only when needed by the plant. Also by creating a drier micro-climate in the plant canopy, the risks posed by plant diseases, which thrive in moist conditions, are also greatly reduced. Drip irrigation can provide additional advantages such as a precise delivery system for plant protectants without harming beneficial insects or the environment.  With these benefits, why don’t we see more drip irrigation used in Wisconsin?   Simple, the high costs of implementing this technology have limited its use, and it remains unclear if these benefits could justify its use in more humid climates with a drought-sensitive crop like potatoes.

Looking to the future where sustainable use of water resources in potato production has emerged as one of the industry’s highest priorities, Sarah Page, a UW-Madison Masters student in Agroecology and Horticulture under the direction of AJ Bussan, has conducted research trials at the Hancock Agricultural Research Station to address just those questions. She compared tuber yield, size and processing quality under standard center pivot irrigation practices and three rates of drip irrigation for commonly grown potato varieties. She found little effect of irrigation treatment and in most years and with most varieties, there were no differences in total yield or tuber size distribution. Surprisingly, the lowest water application rate for drip irrigation yielded slightly higher than the other two rates. This was likely due to increased nutrient leaching under the more heavily irrigated plots, which was supported by nitrate levels detected in plant tissues. A potential negative consequence of lowering irrigation amounts could be drought and heat stress on the tubers, which could have negative consequences for processing quality. However, when Sarah looked into this, she found little effect of irrigation treatment on reducing- sugar content – a contributing factor to undesirable dark colors when potatoes are fried.

Sarah’s research shows that it was possible to reduce water application rates by 25% without negatively affecting potato yield and quality attributes. That’s a lot! There are many steps that need to happen before drip irrigation could be economically feasible and sustainable on a large scale in the sands of Wisconsin, but it’s one more potential tool to add to the box.

For more information, contact Sarah Page at sapage@wisc.edu.

Plants, Water, and Landscapes

Blog 17When it is warm and dry, you have probably noticed that plants require a lot of water to stay healthy, but did you know that only 10% of the water a plant receives actually remains inside of it to support life processes? Plants lose the other 90% of their required water (liquid) as water vapor (gas) to the atmosphere through a process known as evapotranspiration (ET), which is a combination of water the plants emit from pores in their leaves (transpiration) and water that evaporates from soil and plant surfaces.  ET uses a tremendous amount of solar energy, and this energy use coupled to the plant water use is referred to as the water-energy cycle of a landscape. When humans alter the composition of plants across a landscape (i.e. urbanization, agriculture), they also alter the water-energy cycle.  (more…)

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