Harvest Weed Seed Control – How It Depletes Soil Seedbank
Some Australian farmers collect chaff in pull-behind carts like this one to keep weed seeds from dispersing.
Some Australian farmers collect chaff in pull-behind carts like this one to keep weed seeds from dispersing.
The Soil Seedbank
“Soil seedbank” refers to weed seeds present in the soil. The soil seedbank serves as the source of next season weed problems. The majority of seeds in the soil were deposited by plants that escaped control on the last year. Due to seed dormancy, weed seeds can remain viable in the soil for many years and often emerge over many weeks during the growing season.
Seed dormancy, prolonged viability, and extended emergence periods make it easier for weeds to survive across a wide range of environments and management tactics. Current management recommendations target weed seed production to prevent additions to the soil seedbank. Recommendations include controlling weeds while they are small and susceptible to weed control tactics, removing weeds that escaped control, and managing weeds that produced viable seeds to minimize their impact on the soil seedbank.
These late-season practices are not new, but due to wide-spread herbicide-resistance they are being revisited with new technology. In this video Dr. Mandy Bish explains the importance of understanding the weed seedbank and why preventing weeds from producing seeds is so important.
How to Manage the Soil Seedbank?
Currently there are no economical methods to kill weed seeds once they enter the soil. Weed management practices focus on controlling weeds early in the growing season with herbicides and cultivation, then following up to manage those weeds that escape control and prevent seeds from entering the soil.
Studies have demonstrated that preventing seeds from returning to the soil can rapidly reduce the seedbank and resulting weed densities. Allowing weeds to produce viable seeds, however, can cause rapid increases in weed densities. Stopping seeds from entering the seedbank can be achieved by
- Preventing weeds from producing seeds (no seeds, no weeds)
- Enhancing weed seed predation
- Increasing seed mortality
- Removing seeds from the field before the seeds are shed
- If weeds do produce viable seeds, place seeds in narrow strips with chaff lining to improve management next year.
There has been a renewed emphasis on increasing seed mortality, mechanically removing seeds from the field, and altering the placement of seeds. These were tactics used before the wide-spread use of herbicides. With the technological advances in machinery these tactics are again being researched and adapted for use in various regions.
Palmer amaranth that escaped control during the growing season, with viable seeds ready to return to the soil seedbank. Photo: Claudio Rubione
How to Prevent Adding to the Soil Weed Seed Bank
As cash crop harvest approaches you may discover that weeds have escaped your control efforts and are setting seeds. These weeds may be very visible, poking their heads above the canopy of the cash crop. When you go to harvest the cash crop, you are at risk of spreading the weed seeds.
These escaped weeds will create an even bigger problem next year if they are allowed to add the seeds they have produced back to the soil weed seed bank, or to spread their seeds to new fields by hitching a ride on harvesting equipment. You still have a chance to prevent this from happening.
Scout your fields prior to harvest.
You can scout using drones or other means such as physically walking the fields.
Know where the problem areas are: map them out.
Plan to harvest weed-free areas first and weedy areas last.
Limit the spread of weed seeds through the field and from weedy fields to clean ones. Clean the combine before leaving a field. A single Palmer amaranth plant can produce hundreds of thousands of seeds – planning your harvest strategy and cleaning equipment diligently is well worth the time. Remember: scout, map, and plan prior to harvesting to Get Rid of Weeds!
When to manage the soil seedbank?
Prior to planting
The most common tactics to reduce the soil seedbank include crop rotation and tillage. Diverse crop rotations allow for a diversification of other supporting IWM tools, such as herbicides, tillage, and crop competition. Diversified crop rotations are rarely used to manage the soil weed seedbank. The use of only one (or a few) cash crops ultimately allows weeds with similar traits to thrive, replenishing the weed seedbank annually. Tillage can both increase the soil seedbank (by burying seeds) and decrease it (by unearthing buried seeds that may germinate early and die).
The effect of deep tillage on the soil seedbank can be gauged by knowing the main weed species in a field and understanding how long the seeds of the species stay viable: deep tillage is a better choice for short-lived seeds. Grass weeds tend to have less persistent seeds than broadleaf weeds. Strategic deep tillage affects seedbanks depending on weed traits such as germination and seed size.
A specific tillage tactic to manage the seedbank is the stale seedbed method. Stale seedbed management uses tillage to promote weed germination so that another management tactic can then be used to kill weed seedlings prior to crop planting, reducing the size of the soil seedbank. Crop rotations and tillage are fundamental for weed management, but management decisions tend to prioritize economic and logistic factors over effects on weeds.
Prior and or during harvest
Harvest Weed Seed Control (HWSC) is an approach to managing the soil seedbank. These methods focus on cultural and mechanical options to reduce the impact of seeds from escaped weeds at harvest time. These are only effective for weed species that do not shatter and allow their seeds to shed prior to mechanical harvest.
HWSC tactics include:
- Narrow windrow burning
- Chaff lining
- Chaff tramlines
- Impact mills
- Chaff carts
- Bale direct system
Narrow windrow burning is relatively easy to adopt and can provide good results. Both small and large size weed seeds are controlled. This tactic involves a chute that is attached to the rear of the combine that concentrates the chaff and straw residues into a narrow windrow, which is later burned. At around $250 in materials it is also cost effective.
However, this method is time consuming, removes most of the field ground cover, has a risk of fire escape, may not be legal in all jurisdictions, is not an option for all crops (e.g. corn), and it is difficult to achieve a good burn in long windrows. Narrow windrow burning requires some trial and error. Harvesting low is key to obtaining more crop residue to burn.
Choosing the right time and conditions to burn is critical. A light wind is ideal, but be careful of a gusty day. Current research suggests that narrow windrow burning works best in wheat and soybean cropping systems, but other systems are being tested.
Windrow formation for burning in a wheat field highly infested with Italian ryegrass in Arkansas. Photo: Lauren Lazaro Windrow burning needs to be carefully planned ahead of time. Wind speed and direction, relative humidity, availability of tillage equipment to build preventive fire fences, and access to plenty of fire extinguishers are some of the issues to be considered for safely managing the fire. Photo: Claudio Rubione
Chaff lining is a cost effective HWSC method. Chaff lining takes a chute and diverts only the chaff fraction into a narrow row in the center of the harvester, while the rest of the crop residue is spreadly evenly behind the combine. While weed seeds are returned to the soil, they are in narrow lines instead of being spread across the entire field.
The chaff material is allowed to rot and decay. These lines could be treated differently, using targeted herbicides sprays, or managed with different tools at a site specific level.
A plastic chute fitted to the harvester funnels the chaff containing the majority of weed seeds present into a narrow band in the middle of the CTF run. Photo: Mic Fels
Chaff tramlining forms the chaff material into narrow rows on dedicated wheel tracks during harvest and relies on a mulch effect to prevent weed seed germination and emergence, as in chaff lining (above). Chaff tramlining equipment runs around $15,000 to $18,000 depending on your harvester brand and model.
Chaff tramliners are variable and quite expensive. Photo: Peter Newman, WeedSmart
Impact mills, such as the integrated Harrington Seed Destructor or the Seed Terminator, are integrated into the rear of the combine where an impact mill physically destroys the weed seeds in the chaff fraction.
Weed seed contained in the chaff fraction will depend on the weed species and in how many of the seeds are retained on the weed before harvest Impact mills can be highly effective with over 95% destruction of the weed seeds that enter the mill. The current impact mills are expensive and not available in most countries.
Integrated Harrington Seed Destructor. Collected chaff is sent to the mills, which pulverize weed seeds and small residue into dust, which comes out through the back of the machine. A four year study on the technology is being carried out across the US. Photo: DeBruin Brothers
Chaff carts are the simplest HWSC system, consisting of a chaff collection and transfer mechanism that is attached to a combine that delivers the chaff fraction to a bulk collection bin, usually a trailing cart, that can be physically removed from the field so the chaff can be burned or grazed.
Major downsides to this method are that it adds extra length to the combine so it can be difficult for small fields or fields without much room to navigate and it requires extra time to empty the carts.
Chaff cart pulled behind a combine in Australia. Photo: Michael Walsh, Australian Herbicide Resistance Initiative
The bale direct system consists of a large square baler that is attached directly to the harvester which constructs bales from the chaff and straw residue. There is a limited market for the bales and a large risk of immediately spreading weed seeds to other fields.
The bale direct system provides a new system for harvesting corn and baling corn stover in one simple step. Picture credit: http://biomassmagazine.com/articles/10864/john-deere-hillco-introduce-single-pass-round-bale-system
All of the HWSC methods are similarly effective, but come with different initial costs, operating costs, and residual costs. Additional pros and cons related to feasibility, and level of nutrient removal or redistribution should be considered. The best HWSC method for your farm comes down to cost and other management concerns.
Table 1: Pros and cons of the six different HWSC methods.
High capital cost
While the cost of managing the soil seedbank ranges dramatically by tactic, the end goal is ultimately the same. In the future, knowledge about the links between seedbank density and weed emergence patterns may inform additional soil seedbank management practices.
Managing the Weed Seedbank with Cover Crops and Tillage
Managing the Weed Seedbank with Cover Crops and Tillage
Weed control is a principal concern for vegetable growers. The adoption of sustainable agricultural techniques can reduce land managers’ dependency on expensive or harmful chemicals, but may also result in increased weed presence. Weed control is not just a matter of preventing weed emergence or killing weeds that arise during the growing season. A good management strategy should include reducing the size of the existing weed seedbank. Adopting techniques that reduce the weed seedbank is a necessary step toward long term weed management solutions.
Every plot of land has a seedbank which is made up of seeds that are lying in the soil awaiting acceptable conditions to germinate. Seeds may require specific levels of moisture, temperature, light, disturbance, or sometimes special conditions such as fire to germinate, and seeds of some plant species may lie dormant for years before germinating. Several techniques have been tested for reducing the weed seedbank. One way is to disturb the soil prior to planting crops, allowing weed seeds to germinate. Weed seedlings can then be killed either by mechanical or chemical means. This reduces the weed seedbank and prevents weeds from emerging later in the season and competing with the crop. This is called the “stale seedbed” technique. The stale seedbed takes advantage of another strategy to reduce the weed seedbank, which centers on preventing seeds from entering into the soil. This can be accomplished by killing weeds before they release seeds or using cover crops to suppress weed emergence. Both methods if used appropriately will prevent weeds from replenishing the seedbank.
In two separate field experiments at the University of Maryland Upper Marlboro Research and Education Facility we tested the effects of cover crops (Cover Crop Experiment) and tillage techniques (Tillage Experiment) on the weed seedbank. To accomplish this, we took soil cores (depth = 15 cm) from treatment plots in both experiments prior to mowing cover crops. The soil was evenly spread in plastic flats and placed in favorable greenhouse conditions for six weeks. This allowed the weed seeds present in the seedbank to germinate, after which they were counted and identified. We have three and two years of seedbank data from the Cover Crop and Tillage Experiment, respectively, giving us some early clues as to whether cover crops and tillage can influence the weed seedbank.
Figure 2. Separating soil from roots and debris prior to transport to greenhouse. Field assistant G. Polley.
Cover Crop Experiment
The Cover Crop Experiment consisted of field plots grown with one of three cover crop treatments and a no cover crop check treatment. The three cover crops treatments were (1) barley, seeded at 100lb/A, (2) crimson clover, seeded at 20 lb/A, and (3) a mixture of barley and crimson clover, seeded at 60 and 40 lb/A respectively. Cover crops were planted in the fall of 2011 and 2012, and flail mowed and strip tilled each spring. A vegetable crop was then planted into the tilled strips, leaving cover crop residue between planted rows. We collected seedbank soil cores in 2011 (for a pre-treatment baseline), 2012, and 2013, prior to planting the vegetable crop in early spring or summer.
The Tillage Experiment consisted of field plots planted with a forage radish, rye, and crimson clover cover crop mixture. In the spring, cover crops were flail-mowed and the plots tilled using one of four techniques: (1) no till, where crops were seeded directly into the cover crop residue, (2) strip till, where narrow strips (~12 inches) were tilled for planting the crop, leaving most of the plot covered by cover crop residue, (3) black plastic, where transplants or seed were planted on black plastic mulch after the plots were chiseled plowed and disked, and (4) bare ground, where the plots were plowed and disked after the cover crops were flail-mowed. (For additional details on this experiment, see the article by G. Chen et al. in this issue).
Two years of data from the cover crop study showed that plots grown with crimson clover germinated fewer seeds compared to the other treatments (Figure 4). Two years of data from the tillage study showed that plots containing black plastic have the greatest reduction in the weed seedbank compared to the other treatments (Figure 5). These two experiments had very different numbers of germinating seeds, despite being less than 1 km (~ 0.6 miles) apart. The two experimental field sites were grown under very different conditions prior to these experiments, highlighting the importance of historical land use for the current weed seedbank.
Managing the weed seedbank is a long-term endeavor, but can provide long-term benefits. While these two to three years of data can only serve as an early indication as to how different cover crops and tillage methods might influence the weed seedbank, we do see that techniques offering greater soil coverage might be most effective at managing the weed seedbank. Soil coverage can suppress weed emergence and growth, preventing weeds from releasing seeds back into the soil. Over time, this can reduce the size of the weed seedbank and help provide long term weed management.
These studies are funded by USDA National Institute of Food and Agriculture (NIFA) grants 2011-51106-31203 (Tillage study) and 2010-51300-21412 (Cover crop experiment) that were awarded through the Organic Transitions (ORG) and Organic Research and Extension Initiative (OREI) programs. The goal of these programs are to support the development and implementation of research, extension and higher education programs to improve the competitiveness of organic livestock and crop producers, as well as those who are adopting organic practices. If there are any questions regarding these projects and managing the weed seed bed, feel free to email Amanda Buchanan at [email protected] More information on these and related projects can be found at cerrutirrhookslab.umd.edu/.