Manures for Organic Crop Production

Livestock manure is traditionally a key fertiliser in organic and sustainable soil management. It is most effectively used in combination with other sustainable practices. These include crop rotation, cover cropping, green manuring, liming, and the addition of other natural or biologically friendly fertilisers and amendments. In organic production, manure is commonly applied to the field in either a raw (fresh or dried) or composted state.

Raw manure is an excellent resource for organic crop production. It supplies nutrients and organic matter, stimulating the biological processes in the soil that help to build fertility. Still, a number of cautions and restrictions are in order, based on concerns about produce quality, food contamination, soil fertility imbalances, weed problems, and pollution hazards.

Contamination

Some manures may contain contaminants such as residual hormones, antibiotics, pesticides, disease organisms, and other undesirable substances. Since many of these can be eliminated through high temperature aerobic composting, this practice is recommended where low levels of organic contaminants may be present.

Caution is advised, however, as research has demonstrated that Salmonella and E. coli bacteria appear to survive the composting process much better than previously thought. The possibility of transmitting human diseases discourages the use of fresh manures (and even some composts) as preplant or sidedress fertilisers on vegetable crops – especially crops that are commonly eaten raw.

Washington State University suggests that growers:

• Apply animal manures at least 60 days prior to harvest of any vegetable that will be eaten without cooking. (Note: The NOP’s specific requirements on the timing of manure applications are discussed later in this publication.) If possible, avoid manuring after planting. Fall spreading is advised.
• Do not use dog, cat, or pig manures (fresh or composted). These species share many parasites with humans.
• Wash all produce from manured fields thoroughly before use. Persons especially susceptible to food-borne illnesses (children, the elderly, those with compromised immune systems, etc.) should avoid uncooked produce.

Unlike conventional farmers, who have only safety guidelines regarding manure use, certified organic farmers must follow stringent protocols. Raw manure may NOT be applied to food crops within 120 days of harvest where edible portions have soil contact (i.e., most vegetables, strawberries, etc.); it may NOT be applied to food crops within 90 days of harvest where edible portions do not have soil contact (i.e., grain crops, most tree fruits). Such restrictions do not apply to feed and fiber crops.

Organic substances are not the only contaminants found in livestock manures. Heavy metals can be a problem, especially where industrial scale production systems are used. Concerns over heavy-metal and other chemical contamination have dogged the use of poultry litter as an organically acceptable fertiliser in Arkansas, where it’s readily and cheaply available. Heavy-metal contamination is also a concern with composted sewage sludge (biosolids) – a major reason for its being prohibited from certified organic production.

Under US federal organic standards, certifiers may require testing of manure or compost if there is reason to suspect high levels of contamination.

Produce Quality Concerns

It has long been acknowledged that improper use of raw manure can adversely affect the quality of raw vegetable crops such as potatoes, cucumbers, squash, turnips, cauliflower, cabbage, broccoli, and kale.

As it breaks down in the soil, manure releases chemical compounds such as skatole, indole, and other phenols. When absorbed by the growing plants, these compounds can impart off-flavours and odours to the vegetables. For this reason, raw manure should not be directly applied to vegetable crops; it should instead be spread on cover crops planted the previous season.

Fertility Imbalances

Raw manure use has often been associated with imbalances in soil fertility. There are several causal factors:

• Manure is often rich in specific nutrients like phosphate or potash. While these nutrients are of great benefit to crops, repeated applications of manure can result in their building to detrimental levels. A good example is the overuse of broiler litter in the mid-South, which has put excessive phosphate in the soil and polluted surface waters. Nutrient excesses also “tie up” other minerals. Excessive phosphate interferes with plant uptake of both copper and zinc; excessive potash can restrict boron, manganese, and even magnesium.
• Continual manure use tends to acidify soil. As manure breaks down it releases various organic acids that assist in making soil minerals available – a benefit of manure that is often unrecognised. Over time, however, this process depletes the soil of calcium and causes pH levels to fall below the optimum for most crops. Manures do supply some calcium, but not enough to counterbalance the tendency toward increased acidity. Possible exceptions include caged layer manure (when oyster-shell or similar calcium supplements are fed) and manure from dairy operations where barn lime is used.
• When fresh manure containing large amounts of nitrogen and salts is applied to a crop, it can have the same effects as excessive applications of soluble commercial fertilisers – it can burn seedling roots, reduce immunity to pests, and shorten produce shelf life. Excessive salinity is often associated with heavy applications of feedlot manure in regions where little leaching naturally occurs.

For example, growers in southwestern American states like Arizona are advised to apply gypsum and leach the soil with about 4 inches of irrigation water following incorporation of dairy or feedlot manures.

To avoid manure-induced imbalances, continually monitor soil fertility, using appropriate soil tests. Then apply lime or other supplementary fertilisers and amendments to ensure soil balance, or restrict application levels if needed. A soil audit that measures cation base saturation is strongly advised. If this service is not provided through your state, use of a private lab is suggested.

Understanding the soil’s needs is only part of the equation. You must also know the nutrient content of the manure you’re applying. Standard fertiliser values (such as those shown in Table 1) should be used only for crude approximations. The precise nutrient content of any manure is dependent not only on livestock species, but also on the ration fed, the kind of bedding used, amount of liquid added, and the kind of capture and handling system employed. Also, some traditional assumptions about manure composition may need to be updated. Because of the abundance of sulfur in rations, manure has long been recognised as a good source of sulfur.

However, less sulfur is applied to crops in contemporary high-analysis fertilisers, and atmospheric deposition has been decreased by pollution controls. Sulfur deficiencies are appearing in many soils, and levels in manure may also be diminished. It is advisable to test manure as you would test the soil, in order to assess its fertiliser value.

Weed Problems

Use of raw manures has often been associated with increased weed problems. Some manure contains weed seed, often from bedding materials like small-grain straw and old hay.

High-temperature aerobic composting can greatly reduce the number of viable weed seeds. In many cases, however, the lush growth of weeds that follows manuring does not result from weed seeds in the manure but from the stimulating effect manure has on seeds already present in the soil. The flush of weeds may result from enhanced biological activity, the presence of organic acids, an excess of nitrates, or some other change in the fertility status of the soil. Depending on the weed species that emerge, the problem may be related to the sort of fertility imbalances described above. Excesses of potash and nitrogen in particular can encourage weeds.

Monitor the nutrient contents of soil and manure and spread manure evenly to reduce the incidence of weed problems.

Pollution

When the nutrients in raw or composted manure are eroded or leached from farm fields or holding areas, they present a potential pollution problem, in addition to being a resource lost to the farmer. Leached into groundwater, nitrates from manure and fertilisers have been linked to a number of human health problems. Flushed into surface waters, nutrients can cause eutrophication of ponds, lakes, and streams.

The manner in which manure is collected and stored prior to field use affects the stabilisation and conservation of valuable nutrients and organic matter. Composting is one means of good manure handling and is discussed in more detail below.

Reducing manure run-off and leaching losses from fields is a matter of both volume and timing. Manure application far in excess of crop needs greatly increases the chances of nutrient loss, especially in high-rainfall areas. Manure spread on bare, frozen orerodible ground is subject to run-off, especially where heavy winter rains are common. Under some conditions, however, winter-applied manure can actually slow run-off and erosion losses from fields, likely by acting as a light organic mulch.

Sheet-composting manure (tilling it into the soil shortly after spreading) or applying it to growing cover crops are two advisable means of conserving manure nutrients. Grass cover crops, such as rye and ryegrass, are especially good as “catch crops” – cover crops grown to absorb soluble nutrients from the soil profile to prevent them from leaching. (All cover crops function as catch crops to a greater or lesser degree.) It is a sound strategy, therefore, to apply manure to growing catch crops or just prior to planting them.

Note that both sheet composting and applying to cover crops have trade-offs. Sheet composting improves the capture of ammonia nitrogen from manure, but requires tillage, which leaves the soil bare and vulnerable to erosion and leaching losses. Surface-applying to cover crops (with no soil-incorporation) eliminates most leaching and erosion losses but increases ammonia losses to the atmosphere.

Composted Manures

An effective composting process converts animal wastes, bedding, and other raw products into humus – the relatively stable, nutrient-rich, and chemically active organic fraction found in fertile soil. In stable humus, there is practically no free ammonia or soluble nitrate, but a large amount of nitrogen is tied up as proteins, amino acids, and other biological components. Other nutrients are stabilised in compost as well.

Composting livestock manure reduces many of the drawbacks associated with raw manure use. Good compost is a “safe” fertiliser. Low in soluble salts, it doesn’t “burn” plants. It’s also less likely to cause nutrient imbalances. It can safely be applied directly to growing vegetable crops. Many commercially available organic fertilisers are based on composted animal manures supplemented with rock powders, plant by-products like alfalfa meal, and additional animal byproducts like blood, bone, and feather meals.

The quality of compost depends on the feedstuffs used to make it. Unless it is supplemented in some way, composted broiler litter – though more stable than raw litter – will be abundant in phosphates and low in calcium. Continued applications may lead to imbalanced soil conditions in the long term, as with some raw manures. Soil and compost testing to monitor nutrient levels is strongly advised.

While composting can degrade many organic contaminants, it cannot eliminate heavy metals. In fact, composting concentrates metals, making the contaminated compost, pound for pound, more potentially hazardous than the manure it was created from. Broiler litter and broiler-litter composts have been restricted from certified organic production largely for this reason. Arsenic – once used in chicken feed as an appetite stimulant and antibiotic – was a particular concern. Since the precise composition of commercial livestock feeds is proprietary information, arsenic may still be an additive in formulations in some regions.

A more recent concern is the inclusion of additional copper in poultry diets and its accumulation in the excreted manure. While copper is an essential plant nutrient, an excessive level in the soil is toxic. This concern is most relevant to organic horticultural producers, who often apply significant amounts of copper as fungicides and bactericides, increasing the hazard of buildup in the soil. Whenever you import large amounts of either composted or raw manure onto the farm, it is wise to inquire about the feeding practices at the source or have the material tested.

The NOP has put no specific restrictions on when farmers can apply composted manure to crops; however, it is very specific about manure composting procedures. According to the NOP Regulations, compost must meet the following criteria:

• An initial carbon:nitrogen ratio of between 25:1 and 40:1 must exist for the blend of materials in the “pile”; and •Temperatures between 131° F and 170° F must be sustained for three days using an in-vessel or static aerated pile system; or
• Temperatures between 131° F and 170° F must be sustained for 15 days using a windrow composting system, during which period the materials must be turned a minimum of five times.

The National Organic Standards Board – the advisory body to the NOP – has recommended a more flexible interpretation of the compost rules, but this has not yet been incorporated into the legislation.

Guano

Guano is the dried excrement of various species of bats and seabirds. It has a long history of use as an agricultural fertiliser. It was apparently highly prized by native Peruvians well before the Spanish conquest. Before the development of chemical fertilizers, there was US Government support for entrepreneurs who discovered and developed guano deposits.

The nutrient content of commercial guano products can vary considerably based on the diet of the birds or bats. Seabirds subsist largely on fish; depending on the species, bats may thrive largely on insects or on fruits. Another major factor is the age of the source deposit. Guano products may be fresh, semi-fossilised, or fossilised.

As a nutrient source, guano is considered to be moderately available, as are most manures. One source suggests that guanos are rich in “bioremediation microbes” that assist in cleaning up soil toxins. If true, this would make guano an excellent amendment to use when transitioning from conventional to more sustainable production systems.

Guano is advertised as being quite safe and non-burning to plants; “foolproof” is the term sometimes employed. There does not appear to be any evidence to the contrary. There is, however, one serious human illness connected with guano. Histoplasmosis, caused by the fungus Histoplasm capsulatum, produces symptoms similar to influenza in mild cases, or pneumonia when severe. In persons with compromised immune systems plasmosis can produce complications leading to death.

Therefore respirators and masks are recommended when handling guanos. Also, clothing should be removed carefully afterwards to avoid inhaling accumulated dusts. If possible, wet down the pile of dried guano to reduce dust.

At the present time, the NOP regulations treat guano as raw, uncomposted manure. It is therefore subject to the same 90- and 120-day application restrictions. It is relatively safe but rather expensive for organic production. Its use is best justified on high-value crops.

Field-applying Manures & Composts

When

The 90- and 120-day restrictions on manure application are mainly intended to prevent food contamination with manure pathogens. Beyond these timing constraints, however, additional agronomic considerations are involved in scheduling manure applications.

Generally, manures and composts have their strongest effect on a crop or cover crop if applied just in advance of planting. Growers of agronomic crops commonly apply them to the most nitrogen-hungry and responsive crops. In midwestern organic rotations, this would likely be corn. While the small-grain crop would respond positively to manure, it is a relatively low-value crop and therefore resides at the bottom of the pecking order when manure resources are in short supply.

The circumstances are a bit more complex with vegetable crops. According to experienced market gardener and author Eliot Coleman, crops like squash, corn, peas, and beans do best when manure is spread and incorporated just prior to planting. The same holds true for leafy greens, though only well-composted manure should be used. Cabbages, tomatoes, potatoes and root crops, on the other hand, tend to do better when the ground has been manured the previous year. Obviously, crop rotations that feature non-manured crops following manured crops would be ideal.

To achieve maximum recovery of the nutrients in spread manure, sheet composting – plowing or otherwise incorporating the manure into the soil as soon as possible after spreading – is the best option. Research has shown that solid raw manure will lose about 21% of its nitrogen to the atmosphere if spread and left for four days; prompt soil incorporation reduces that loss to only 5%.

However, since excessive tillage is discouraged in sustainable systems, options for sheet composting may be limited on some farms. The next-best option appears to be spreading onto growing cover crops. This reduces the chances of loss through surface erosion and cuts leaching significantly. However, it does little to control ammonia losses to the atmosphere.

How

One of the weakest links in the use of manure as a fertiliser appears to be the actual process of field spreading. According to some researchers, the conventional box spreader is an “engineering anachronism” – an outdated piece of equipment designed principally to dispose of a waste product, not to manage a nutrient resource. Many machines are built to “dump” as much material as possible in a short time and are difficult to calibrate if you want to distribute manure accurately and according to crop needs. Still, the basic box spreader is the only technology available and affordable to most farmers.

Characteristics to consider when purchasing a spreader (used or new) include:

• Condition of chains, gears, and sprockets. It is common knowledge among farmers that manure spreaders only break down with a full load. Naturally, it is the floor chain – buried under the manure – that is the first item to go.
• Condition of the floor. Acids and moisture in manure corrode and rot metal and wood flooring long before the sides decay. Some manufacturers now make models featuring a plastic floor that is highly resistant to deterioration..
• Condition of paddles. Paddles are designed to shred and break up wads of manure and bedding materials. They also provide some lateral spreading. Since this is rather crude technology, the resulting distribution is generally less even than desired.
• Power drive. Box spreaders are either powered through the tractor PTO or ground-driven. PTO-driven spreaders have more flexibility and can also be used to create windrows for composting.

Box manure spreaders are poor compost spreaders – especially when well-made granular composts are used. Well-made compost is fine, relatively flowable, and is better handled with spreaders suited to broadcasting lime and bulk granular fertiliser. This equipment is much easier to calibrate and provides a more uniform distribution of material.

Summary

Both raw and composted manures are useful in organic crop production. Used properly, with attention to balancing soil fertility, manures can supplant all or most needs for purchased fertiliser, especially when combined with a whole system fertility plan that includes crop rotation and cover cropping with nitrogen-fixing legumes.

The grower needs to monitor nutrients in the soil via soil testing and learn the characteristics of the manure and/or compost to be used. The grower should adjust the rates and select additional fertilisers and amendments accordingly.

Source: ATTRA

ATTRA is the national sustainable agriculture information service operated by the National Center for Appropriate Technology, through a grant from the Rural Business-Cooperative Service, U.S Department of Agriculture.