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Buffalo Creek Nature Preserve Management PlanBuffalo Creek Nature Preserve Management Plan Submitted by: Baxter & Woodman, Inc. Consulting Engineers www.baxterwoodman.com 061234.20 Village of Buffalo Grove, Illinois Buffalo Creek Nature Preserve Management Plan TABLE OF CONTENTS Section Page No. 1. INTRODUCTION 1-1 2. EXISTING CONDITIONS 2-1 3. MANAGEMENT ACTIVITIES 3.1 Flood Control/Bank Stability 3-1 3.2 Infrastructure 3-2 3.3 Vegetation 3-2 3.4 Bird Nest Boxes 3-4 3.5 Educational Signs 3-4 3.6 Recreation 3-5 LIST OF EXHIBITS Exhibit A. Existing Conditions B. Management Plan - Proposed LIST OF APPENDICES Appendix A. Historic Aerial Photographs B. Site Photographs C. Prairie, Wetland, and Forested Floodplain Plants D. Buffalo Creek Forest Preserve E. Management of Invasive Plants 061234 – 07/07 1-1 061234 – 07/07 1. INTRODUCTION This plan provides a basis for management activities at the Buffalo Creek Nature Preserve, a 15-acre Village park located southeast of Arlington Heights Road and Checker Drive. This document includes a discussion of the historical use of the site; describes existing conditions; and proposes management activities to meet the Village’s vision for the park. The site was historically farmed prior to development as a park. Aerial photographs from 1939, 1974, 1993, 2000, 2002, 2004, and 2005 showing the land use of the area are included in Appendix A. The 1939 aerial photograph shows the site as farmed. Buffalo Creek and Aspen Creek are visible, with a narrow, wooded riparian zone next to Buffalo Creek at the east end of the site. The 1974 aerial photograph shows a wider, wooded riparian zone along Buffalo Creek. The rest of the site appears to be grassland/pasture. The site was developed as a park in 1982-83. The 1993 – 2005 aerial photographs show various phases of park maturity. 2-1 061234 – 07/07 2. EXISTING CONDITIONS The Buffalo Creek Nature Preserve contains several types of habitat. Important habitats include Buffalo Creek and its associated floodplain forest; Aspen Creek; the prairie- wetland complex; and park areas consisting of upland trees and turf grass. Exhibit A shows the location of these different types of habitat on an aerial photograph. Buffalo Creek consists of a series of pools and riffles flowing from west to east across the south end of the Preserve. In 2006, the Village removed the fallen trees within the creek that were causing flooding and erosion problems. Healthy trees in good condition were left along the banks. Buckthorns were removed along the north bank to provide access to Buffalo Creek. This clearing was seeded with native herbaceous plants in the fall of 2006. Photos of Buffalo Creek and the rest of the Preserve are provided in Appendix B. The floodplain forest ranges 200 to 400 feet wide along Buffalo Creek. Common trees include box elder, cottonwood, silver maple, and black cherry. This forest is relatively young since it was previously cleared and used for agricultural purposes. The shrub layer is dominated by common buckthorn, a non-native, invasive shrub. Garlic mustard, another non-native, invasive plant, is common in the herbaceous layer. Deer browsing of plants is evident. A list of plants observed in the floodplain forest is included in Appendix C. Aspen Creek flows north to south through the Nature Preserve to Buffalo Creek. On either side of Aspen Creek lie wetland areas. These wetland areas were constructed in 1982- 83 to provide compensatory flood storage for the Lexington Glen development immediately south of the Nature Preserve. A list of plants observed in the wetland areas is included in Appendix C. 2-2 061234 – 07/07 A prairie surrounds the wetland areas between Checker Drive and the floodplain forest. A variety of native prairie plants, as a result of seeding efforts in the 1980s, occur at the Nature Preserve. A list of plants observed in the prairie areas is included in Appendix C. A variety of trees were planted for past Arbor Day celebrations in the northwest corner of the Preserve. Trees include white pine, cedars, hawthorns, honey locust, and ash. Ash is also a common tree in the northeast corner of the Preserve. Residents can enjoy the Buffalo Creek Nature Preserve through a system of paved paths throughout the Preserve. Access is available from Arlington Heights Road; Checker Drive; Buffalo Creek Forest Preserve via a path under Arlington Heights Road; and from the south via a bridge across Buffalo Creek at the east end of the Preserve next to the Golf Course. The paved path is currently in good condition. There are three benches along the path for rest and relaxation. Also, there are three educational signs along the path describing natural area topics. Since the Nature Preserve lies along a greenspace corridor, with the Buffalo Creek Forest Preserve to the west and the Buffalo Grove Golf Course to the east, a variety of wildlife utilize the Nature Preserve (a copy of the Buffalo Creek Forest Preserve conceptual plan is shown in Appendix D). There are six bird-nesting boxes within the Forest Preserve. Two of these are along Aspen Creek and built for wood ducks. The other four are songbird (e.g., bluebird) boxes located around the prairie. 3-1 061234 – 07/07 3. MANAGEMENT ACTIVITIES Two important functions of the Buffalo Creek Nature Preserve are to provide a natural area that residents can enjoy and to store floodwaters. Management activities to address these functions include maintaining bank stability and flood hydraulics of Buffalo Creek and Aspen Creek; maintaining infrastructure; manage the natural areas to increase the diversity of plants and wildlife; and provide access for residents. These management activities are discussed below. 3.1 Flood Control/Bank Stability Buffalo Creek is a major watercourse flowing through the Village. Even though there is a flood control reservoir upstream of Arlington Heights Road, Buffalo Creek can overtop its banks and flood residential homes. Maintaining stream hydraulics to minimize flood damages is an important task the Village performs each year. This includes the removal of fallen trees and debris from Buffalo Creek. In 2006, the Village removed a large amount of fallen trees from Buffalo Creek within the Nature Preserve. Fallen trees and limbs can create debris log jams, causing localized flooding and erosion of the streambank. Although woody debris in streams is natural and provides aquatic habitat, any accumulation of woody debris that could lead to a log jam or erosion of streambanks should be removed. Routine inspection of the stream, two-to- four times a year, would identify fallen logs and other debris to be removed. The debris should be removed immediately when it is deemed to be a hazard. The Village should also routinely monitor the streambanks for erosion. A rod driven into the side of the bank can be used as a tool to monitor the loss of soil from the streambank. 3-2 061234 – 07/07 With the chance of children playing along the banks, a plastic rod or similar device that does not have any sharp edges or safety hazards should be used. Three plastic rods were driven into the bank in June 2007, with six inches of the rod exposed (Exhibit A). Reaches with excessive erosion should be stabilized using biotechnical approaches. Biotechnical approaches are currently being used along Buffalo Creek within the Buffalo Grove Golf Course. 3.2 Infrastructure The two major infrastructure components at the Preserve are the paved paths and stream crossings. The paved path system should be regularly inspected for faulty pavement and replaced/repaired where necessary. The Village currently has a pavement inspection program, plus the path is inspected during routine mowing operations. Currently, the pavement is in good condition. There are three stream crossings for the path system: two culvert crossings of Aspen Creek and the pedestrian bridge at Buffalo Creek. The headwall on the south side of Checker Drive has cracked concrete and a loose handrail post. The headwall and railing should be repaired for pedestrian safety. A small amount of rock riprap can be placed along the headwall to prevent scouring. The banks are stable with good vegetative growth. The dual culverts along Aspen Creek near Buffalo Creek are in good shape but show signs of scouring, especially the northeast corner. To help protect these culverts, rock riprap can be placed next to the culverts and a rock vane can be placed just upstream to direct the flow to the center of the culverts. The banks are stable with good vegetative growth. 3-3 061234 – 07/07 The pedestrian bridge should be regularly inspected. Currently, the stream banks and gabion baskets are in good shape. 3.3 Vegetation Common buckthorn, honeysuckle, and garlic mustard, non-native invasive plants, occur within the floodplain forest. These plants should be removed in order to increase the diversity of plants (i.e., they shade and outcompete the native herbaceous plants) and attract more wildlife. Supplemental plantings of floodplain trees, such as swamp white oak, would help increase the diversity of deciduous trees. Management methods to control these invasive plants are included in Appendix E. The prairie-wetland complex is burned approximately once every three years. Fire is a natural component of prairies and some wetlands. Fire discourages the growth of non- native, cool-season weeds. This is a good natural area practice that should be continued to keep a diversity of plants. There are several pockets of invasive plants that should be addressed so they do not expand. There are patches of common reed and willow shrubs reducing the floral diversity in those locales. Also, reed canary grass should be controlled to reduce expansion of this invasive grass. Other invasive plants observed throughout the prairie that should be controlled include crown vetch, sweet clover, teasel, nodding thistle, canada thistle, and queen anne’s lace. Methods to control invasive plants are included in Appendix E. There are isolated trees within the prairie that can remain. However, there are some tree clones via root suckers. These tree clones should be removed and the cut stumps treated 3-4 061234 – 07/07 with Garlon or similar herbicide. Some trees can remain to provide perching habitat for birds. There are many ash trees within the Nature Preserve. The emerald ash borer (EAB) is a beetle that kills ash trees. The Village should continue to monitor the trees for EAB. If detected, work with the Department of Natural Resources and other communities to remove ash trees from infested areas. 3.4 Bird Nest Boxes The songbird nest boxes were installed to attract grassland/meadow species. Woody vegetation within 100 feet of a nest is recommended to be removed, especially the westernmost nest box that is covered by multiflora rose. Woody vegetation provides hiding places for potential predators of grassland bird species, therefore, these birds will not use the nest boxes. Also, nest boxes can be installed within the interior of the prairie-wetland away from the pedestrian path and any human interference. Any new nest box should be removable so that it can be removed during prairie burns. 3.5 Educational Signs The three existing environmental educational signs are fading and becoming difficult to read. New signs can be installed explaining natural resource themes. Topics can include: 1. What is a Watershed? describing the Buffalo Creek watershed. 2. Water Quality Practices explaining the benefits of wetlands, pet waste management, fertilizer management or similar practice. 3. Flood Control. 4. Prairies/Wetlands/Floodplain Forest. 3-5 061234 – 07/07 5. Wildlife. 6. Invasive Species & Control 3.6 Recreation Currently there is no access to Buffalo Creek, except for the pedestrian bridge at the east end. A new trail along the north side of Buffalo Creek is recommended to provide access for residents and Village maintenance crews. The maintenance crews can utilize this path to remove hazardous debris without destroying, then restoring, the soil each time they have an assignment at the creek. A paved path along Buffalo Creek connecting to the existing trail system would be approximately 1,400 feet long and would cost approximately $100,000 to design and construct (2007 dollars). There is a hawthorn shrub along the south side of the recreational path just west of Aspen Creek. Branches with thorns protrude onto the path. This small tree should be removed for safety reasons. 4-1 061234 – 07/07 4. SUMMARY OF RECOMMENDED MANAGEMENT ACTIVITIES 1. Regularly inspect Buffalo Creek for hazardous debris and erosion. Address as appropriate. 2. Regularly inspect paved paths. Address as appropriate. 3. Regularly inspect stream crossings. 4. Repair headwall immediately south of Checker Drive. 5. Protect Aspen Stream dual culverts (just north of Buffalo Creek) from scouring. 6. Control invasive plants (e.g., buckthorn, garlic mustard) in floodplain forest. 7. Maintain natural area burns for the prairie-wetland complex. 8. Control invasive plants in the prairie-wetland complex. Species to control include common reed, reed canary grass, willow thickets, crown vetch, sweet clover, teasel, nodding and canada thistle, queen anne’s lace, and clonal trees (root suckers). 9. Monitor ash trees for emerald ash borer. 10. Remove woody plants around songbird nest boxes. Install additional nest boxes within interior of prairie-wetland complex. 11. Install new environmental education signs. 12. Install new paved path along Buffalo Creek. 13. Remove vegetation that may become hazardous to users of the recreational path. APPENDIX A HISTORIC AERIAL PHOTOGRAPHS APPENDIX B SITE PHOTOGRAPHS Photo 1. Looking south at prairie at west end of prairie. Photo 2. Looking west at paved path along Checker Drive. Photo 3. Looking east along paved path at NW end of prairie/Checker Drive. Photo 4. Sign for Switchgrass at NW corner of prairie. Photo 5. Bench at west end of prairie. Photo 6. Sign for bluebird nest box. Nesting box covered with multiflora rose. Photo 7. Looking southeast at prairie near bluebird nest box sign. Photo 8. Looking south at turf grass/tree area along Arlington Heights Road. Photo 9. Looking north at prairie near park bench. Photo 10. Looking east at paved path near park bench. Photo 11. Looking west at paved path near park bench. Photo 12. Looking northeast at paved path. Note hawthorn encroaching onto path. Photo 13. Bird nest box just west of willows. Photo 14. Looking northwest at prairie/wetland. Photo 15. Looking east at culvert at south end of Aspen Creek. Photo 16. Looking north at Aspen Creek. Photo 17. Looking east at paved path. Photo 18. Looking northeast. Photo 19. Woodland Sunflower sign (faded) at SE corner of prairie. Photo 20. Looking northwest near Woodland Sunflower sign Photo 21. Looking upstream (west) at Buffalo Creek from bridge. Photo 22. Looking south at Lexington Glen development. Photo 23. Looking upstream (west) at Buffalo Creek. Photo 24. Looking east, pedestrian bridge in background. Photo 25. Looking upstream (west) at Buffalo Creek. Photo 26. Looking southwest at former creek crossing for farm vehicles. Photo 27. Buffalo Creek at confluence with Aspen Creek. Photo 28. Looking northeast at Buffalo Creek at confluence with Aspen Creek. Photo 29. Looking south at Lexington Glen storm sewer outfall. Photo 30. Looking west. Photo 31. Looking upstream (northwest) at Buffalo Creek. Photo 32. Looking west at underpass at Arlington Heights Road. Photo 33. Looking south at common reed (Phragmites australis) area. Photo 34. Looking north at Checker Drive culvert and headwall. Photo 35. Looking east at Buffalo Creek at west end. Photo 36. Looking east across prairie from west end. Photo 37. Looking east across prairie. Photo 38. Looking north at Aspen Creek. Photo 39. Looking northeast across prairie. Photo 40. Looking west at bike path and prairie. Photo 41. Looking west at Buffalo Creek. Photo 42. Looking west at Buffalo Creek. APPENDIX C PRAIRIE, WETLAND, AND FORESTED FLOODPLAIN PLANTS Prairie Scientific Name Common Name Andropogon gerardii Big Bluestem Grass Andropogon scoparius Little Bluestem Grass Apocynum sibiricum Prairie Indian Hemp Aster novae-angliae New England Aster Bouteloua curtipendula Side-Oats Grama Carduus nutans Nodding Thistle Carex cristatella Crested Oval Sedge Chrysanthemum leucanthemum Ox-Eye Daisy Cirsium arvense Canada Thistle Coronilla varia Crown Vetch Daucus carota Queen Anne's Lace Dipsacus laciniatus Cut-Leaved Teasel Echinacea purpurea Broad-leaved Purple Coneflower Erigeron annuus Annual Fleabane Eryngium yuccifolium Rattlesnake Master Gleditsia triacanthos Honey Locust Helianthus sp. Sunflower Melilotus alba White Sweet Clover Melilotus officinalis Yellow Sweet Clover Monarda fistulosa Wild Bergamot Panicum virgatum Switch Grass Parthenium integrifolium Wild Quinine Penstemon digitalis Foxglove Beard Tongue Petalostemum purpureum Purple Prairie Clover Poa pratensis Kentucky Blue Grass Populus deltoides Cottonwood Potentilla recta Sulfur Cinquefoil Pycnanthemum virginianum Common Mountain Mint Ratibida pinnata Gray-Headed Coneflower Rosa multiflora Multiflora rose Silphium lacinatum Compass Plant Silphium terebinthinaceum Prairie Dock Solidago altissima Tall Goldenrod Solidago rigida Stiff Goldenrod Sorghastrum nutans Indian Grass LIST OF PLANTS OBSERVED VILLAGE OF BUFFALO GROVE, ILLINOIS BUFFALO CREEK NATURE PRESERVE Page 1 of 3 LIST OF PLANTS OBSERVED VILLAGE OF BUFFALO GROVE, ILLINOIS BUFFALO CREEK NATURE PRESERVE Wetland Scientific Name Common Name Acer saccharinum Silver Maple Apocynum sibiricum Prairie Indian Hemp Asclepias incarnata Swamp Milkweed Aster novae-angliae New England Aster Aster simplex Panicled Aster Cirsium arvense Canada Thistle Coronilla varia Crown Vetch Eleocharis erythropoda Red-Rooted Spike Rush Fragaria virginiana Wild Strawberry Fraxinus pennsylvanica s. Green Ash Geum laciniatum trichocarpum Rough Avens Helianthus grosseserratus Sawtooth Sunflower Juncus dudleyi Dudley's Rush Juncus nodosus Joint Rush Lycopus americanus Common Water Horehound Phalaris arundinacea Reed Canary Grass Phragmites australis Common Reed Physostegia virginiana Obedient Plant Populus deltoides Cottonwood Rhamnus cathartica Common Buckthorn Sagittaria latifolia Common Arrowhead Salix interior Sandbar Willow Salix nigra Black Willow Salix x rubens Hybrid Crack Willow Spartina pectinata Prairie Cord Grass Typha sp. Cattails Verbena hastata Blue Vervain Page 2 of 3 LIST OF PLANTS OBSERVED VILLAGE OF BUFFALO GROVE, ILLINOIS BUFFALO CREEK NATURE PRESERVE Forested Floodplain Scientific Name Common Name Acer negundo Box Elder Acer saccharinum Silver Maple Alliaria petiolata Garlic Mustard Allium canadense Wild Onion Ambrosia artemisiifolia Common Ragweed Ambrosia trifida Giant Ragweed Apocynum sp. Dogbane Arctium minus Common Burdock Carduus nutans Nodding Thistle Cirsium arvense Canada Thistle Convolvulus sepium Hedge Bindweed Fraxinus pennsylvanica s. Green Ash Lysimachia nummularia Moneywort Melilotus officinalis Yellow Sweet Clover Morus alba White Mulberry Oxalis europaea Tall Wood Sorrel Parthenocissus quinquefolia Virginia Creeper Populus deltoides Cottonwood Prunus serotina Black Cherry Rhamnus cathartica Common Buckthorn Rhamnus frangula Glossy Buckthorn Rosa multiflora Multiflora rose Rubus occidentalis Black Raspberry Salix nigra Black Willow Smilacina racemosa Feathery False Solomon's Seal Solanum dulcamara Bittersweet Nightshade Solidago altissima Tall Goldenrod Thalictrum dasycarpum Purple Meadow Rue Notes Italics = non-native plant Page 3 of 3 APPENDIX D BUFFALO CREEK FOREST PRESERVE APPENDIX E MANAGEMENT OF INVASIVE PLANTS (Sources: Invasive Plants Association of Wisconsin; Plant Conservation Alliance; Wisconsin Department of Natural Resources) Invasive Plants Association of Wisconsin 1 http://IPAW.org Buckthorn Identification & Control European buckthorn is a troublesome exotic invasive that spreads readily through woods and savannas. It is a major threat to Wisconsin’s ecosystems. Invasion of a pine forest by buckthorn. Such a dense cover reduces light to the forest floor, thus effectively eliminating native vegetation. Characteristics Common buckthorn (Rhamnus cathartica) and its relative glossy buckthorn (Rhamnus frangula) are serious invaders of Wisconsin’s wooded areas. They also commonly invade hedge rows of open fields, from which they may gradually spread throughout a whole field. Both common and glossy buckthorn are small trees or shrubs that can reach a height of 20-25 feet. Buckthorn most often grows as a shrub, where it may send out several shoots. The outer bark is dark gray or brown, and when cut the inner bark is brown, red, or orange. Buckthorn has separate male and female plants; the latter are often easy to recognize because they produce copious amounts of deep purple berries. It is especially important to remove the berry-producing plants, because they will otherwise be a constant source of infection for the area. Status Buckthorn is of Eurasian origin and was introduced in North America as an ornamental. It was planted for hedge rows in Wisconsin as early as 1849. Despite its insidious nature, it is still legally sold in the state as an ornamental. It has become naturalized and has spread over most of the southern and eastern parts of the state. Buckthorn is an especially troublesome invader of natural oak savanna and oak woodland areas of southwestern Wisconsin. Characteristic orange inner bark of buckthorn. “Scratching the surface” is a good way of ensuring that one has a buckthorn plant. Invasive Plants Association of Wisconsin 2 http://IPAW.org Many bird species relish buckthorn berries. However, the berries contain a chemical which acts as a laxative (hence the species name cathartica). The defecation by the birds insures the spread of the seeds through the habitat. Since female trees may produce abundant fruit, within a few years there can be thousands of buckthorn seedlings in the area of a mature tree. Buckthorn seeds are able to remain alive in the soil for years, and new seedlings will continue to appear for years after the plants have been removed from an area. Buckthorn threats · Destroys wildlife habitat · Replaces native vegetation · Forms an impenetrable understory layer · Causes long-term decline of a forest by preventing the growth of native tree seedlings Control Early identification, before seed production has started, is vital. Small buckthorn seedlings can be readily removed by hand, or with the use of a “weed wrench.” Although effective, mechanical removal disturbs the soil and encourages reinfestation or colonization of other weeds so that loose soil should be tamped down to make a firm surface. Fire Controlled burns will usually top-kill seedings or small buckthorn trees, but does not eradicate them. In order to control buckthorn by controlled burning, it is essential that fire be continued annually until native (fire-resistant) vegetation has become established. Use of fire is best reserved for fire-dependent ecosystems such as prairies or oak savannas. Herbicides There are several herbicides that are very effective in control of buckthorn. One of the most effective is triclopyr (Garlon; Dow Agrochemical). When using an herbicide, it is essential that the label on the package be read completely before use. Basal bark treatment An effective way to control buckthorn is by the use of basal bark treatment with Garlon in oil. Treatment is best done in the late fall or winter when native vegetation has died back and will not be affected. Because buckthorn plants retain their leaves long after native vegetation has lost its leaves, they are readily recognized in the late fall. A concentration of 12-15% triclopyr (active ingredient) in diesel fuel or kerosene is recommended by the manufacturer. Use the herbicide in a backpack sprayer with a nozzle that produces a solid cone or flat fan spray. Spray the lower part of the trunk in such a manner that it becomes thoroughly wet, including the root collar, but not to the Leaves and fruit of common buckthorn, Rhamnus cathartica. Invasive Plants Association of Wisconsin 3 http://IPAW.org point of runoff. Each s tem of the plant must be treated. Properly done, this basal bark treatment is extremely effective and the plant will not leaf out the following growing season. Once dead, the plant can be cut and removed, or allowed to stand to rot. Cutting followed by herbicide treatment of the cut stumps Another very effective way of eradicating buckthorn is to cut the plant just above the ground level and treat the cut stump with triclopyr. The same concentration of triclopyr should be used as for basal bark treatment, but only the cut stump should be treated. It is useful to include a blue or red dye in the herbicide mixture so that the cut stump treatment can be monitored. A backpack sprayer or spray bottle can be used. Be sure that the stump is thoroughly wetted with herbicide. This procedure is economical of herbicide and confines the chemical to the stump itself, but is more labor- intensive than basal bark treatment. However, it has the advantage that the buckthorn plants themselves are being removed from the habitat. Although the cut stump proc edure can be used at any time of the year, the fall or winter is preferable because nontarget plants are not affected. Also, this procedure is effective with plants of any size, even large ones. Place all the cut material in a pile for subsequent burning. Basal bark or cut stump? Bark treatment is best in large infected areas, whereas cutting and treating the cut stumps is best in relatively small areas, or in areas of high interest. It should be emphasized that cutting buckthorn without treating the cut stumps is ill advised, because cut plants will resprout heavily from the roots, leading to a worse situation than if the plant had not been cut at all. First-year plants Garlic mustard is a biennial; it has a two-year life cycle. Seeds germinate in April. Seedlings are shown below. Note oak leaves for size comparison. Leaves: Clusters of 3-8 rounded to kidney- shaped leaves develop at ground level during the first growing season. They have scalloped edges, a wrinkled appearance, and remain green all winter. Second-year plants Flowers: Small (1/4 inch), white, 4 petals, on the end of the main stem and side branches, blooms April through June. (see top of page) Leaves: Heart-shaped to triangular, 1-3 inches wide, coarsely toothed on edges, alternate on the stem, give off a garlic odor when crushed. Height: Flowering stalks grow 1-4 feet tall. Roots: Taproot is slender, white, and often has an S-shaped bend near the top. Seeds: Capsules appear soon after flowering and quickly lengthen. Seeds are small, produced in a row inside the capsule, and black when ripe. More than 100 seeds per plant. Similar species ✔Violet leaves resemble first-year plants, but flowers bloom low and have 5 petals, leaf surfaces are less crinkly. No taproot. ✔Ground ivy (creeping Charlie) spreads along the ground as a vine and has purple flowers. Impacts on forests Out-competes many tree seedlings and other native vegetation. Adversely affects native insects and other wildlife. 4-petaled flowers Control strategies must be applied for eight or more years until the garlic mustard seed bank is depleted. Methods may vary over time, depending on the extent of the invasion. Vulnerable areas, especially woodlands, should be monitored each spring to promptly detect new invasions and prevent re-occurrence. Mark areas where plants were found to aid in future monitoring. Hand Pulling For smaller infestations or where large groups of people are involved, hand pulling or digging garlic mustard can be effective. ✔If plants are pulled or dug before budding begins, they may be scattered about the area to dry out, preferably off the ground. Do not put pulled plants in piles where roots may stay moist and development can continue. ✔Once flowering has begun, all plants must be bagged. Garlic mustard seeds can still ripen after plants are uprooted! (using energy stored in stems and leaves.) Pulled plants may be put in plastic bags or large paper bags. ✔Bagged plants should be disposed of by burning, burying deeply in an area that will not be disturbed, or landfilling. (Please, do not burn plastic bags.) Let garlic mustard collected in paper bags dry thoroughly before burning. ✔Do not compost garlic mustard. Few compost piles produce enough heat to destroy all garlic mustard seeds. ✔To send bagged plants to the landfill, label the bags as ‘Invasive Plants – approved by DNR for landfilling’. Cutting Cutting plants a few inches above the soil surface just after the flower stalks have elongated but before the flowers have opened can be effective in preventing seed production and may kill garlic mustard plants. However, some plants may send out new flower stalks that require additional cutting. Monitor site regularly. Herbicides ✔Extensive infestations – if too large for manual methods – can be controlled by using a 1% or 2% solution of glyphosate (there are many brands). Apply to the foliage of individual plants and dense patches in fall and/or very early spring. At these times most native plants are dormant, but garlic mustard is green and vulnerable. Glyphosate is a nonselective herbicide that will kill or injure all green non-target plants. Use caution during application, and spray so that herbicide neither drips from the garlic mustard leaves or drifts onto adjacent desired vegetation. The Wisconsin Department of Natural Resources provides equal opportunity in its employment, programs, services, and functions under an Affirmative Action Plan. If you have any questions, please write to Equal Opportunity Office, Department of Interior, Washington, D.C. 20240. This publication is available in alternative format (large print, Braille, audiotape etc.) upon request. Please call 608/267-7494 for more information. PRINTED ON RECYCLED PAPER PUB-FR-350-2006 ✔Use herbicides only when necessary. ALWAYS read the entire herbicide label carefully, following all mixing and application instructions. Wear recommended protective gear and clothing. Weed Torch (for wet conditions) Another method for spot-killing patches of newly germinated seedlings in spring is to “flame” them with a propane weed torch. Flames quickly kill tender seedlings, usually without permanently damaging nearby perennial plants. Use the weed torch cautiously, and only when conditions are wet. ALWAYS contact your local fire control agency prior to using this method. Burning permits may be required. Preventing Further Spread ✔Clean shoes, pockets, pants cuffs and equipment thoroughly after walking or working in infested areas. Garlic mustard seeds are tiny and are often carried off in clothing, shoes and mud. ✔Survey your area for green garlic mustard plants. Plants can be spotted any time they are not covered by fallen leaves or snow. ✔When you find an infestation, remove plants that are producing seed first, working from the least infested to the most infested area. Then remove other plants, again starting with the least infested areas. ✔Monitor non-infested woodlands carefully and frequently. Removing one or two plants before they go to seed is much easier than removing hundreds or thousands later on. Websites http://tncweeds.ucdavis.edu/esadocs/allipeti.html An extensive summary of information about garlic mustard. The Nature Conservancy also has information on many other invasive plants. http://dnr.wi.gov/invasives/fact/garlic.htm A summary of garlic mustard information from the Wisconsin DNR, with links to other sites. http://www.botany.wisc.edu/Wisflora Photos and information on all Wisconsin plants. Credits This factsheet is based on the brochure: Garlic Mustard – A Major Threat to Wisconsin’s Woodlands, by Paul Hartman and Sharon Morrisey, Univ. of Wisconsin-Extension, 2002. It was revised by Colin Kelly, David Eagan, Eunice Padley, Kelly Kearns, and Colleen Matula, WDNR, 2006. Control Methods for Garlic Mustard Designed by L. Pohlod 20 May 2005 Page 1 of 6 Plant Conservation Alliance®s Alien Plant Working Group Xeeds Hone Xild: Alien Plant Invaders of Natural Areas http://www.nps.gov/plants/alien/ FACT SHEET: GIANT REED Common Reed Phragmites australis (Cav.) Trin. ex Steud. Grass family (Poaceae) NATIVE RANGE Eurasia DESCRIPTION Common reed, or Phragmites, is a tall, perennial grass that can grow to over 15 feet in height. In North America, both native phragmites (Phragmites australis ssp. americanus Saltonstall, P.M. Peterson & Soreng) and introduced subspecies are found. Introduced Phragmites forms dense stands which include both live stems and standing dead stems from previous year’s growth. Leaves are elongate and typically 1-1.5 inches wide at their widest point. Flowers form bushy panicles in late July and August and are usually purple or golden in color. As seeds mature, the panicles begin to look “fluffy” due to the hairs on the seeds and they take on a grey sheen. Below ground, Phragmites forms a dense network of roots and rhizomes which can go down several feet in depth. The plant spreads horizontally by sending out rhizome runners which can grow 10 or more feet in a single growing season if conditions are optimal. Please see the table below for information on distinguishing betweeen native and introduced Phragmites. ECOLOGICAL THREAT Once introduced Phragmites invades a site it quickly can take over a marsh community, crowding out native plants, changing marsh hydrology, altering wildlife habitat, and increasing fire potential. Its high biomass blocks light to other plants and occupies all the growing space belowground so plant communities can turn into a Phragmites monoculture very quickly. Phragmites can spread both by seed dispersal and by vegetative spread via fragments of rhizomes that break off and are transported elsewhere. New populations of the introduced type may appear sparse for the first few years of growth but due to the plant’s rapid growth rate, they will typically form a pure stand that chokes out other vegetation very quickly. DISTRIBUTION IN THE UNITED STATES Phragmites occurs throughout the lower 48 states and southern Canada. It has been reported to be invasive in natural areas in 18 states including Colorado, Connecticut, Delaware, Georgia, Indiana, Kentucky, Maryland, Michigan, North Carolina, New Hampshire, New Jersey, New York, Ohio, Pennsylvania, Tennessee, Virginia, Vermont, and Wisconsin, and the District of Columbia. HABITAT IN THE UNITED STATES Tidal and nontidal brackish and freshwater marshes, river edges, shores of lakes and ponds, roadsides, disturbed areas. BACKGROUND Preserved remains of native Phragmites that are 40,000 years old have been found in the southwest indicating that it is a part of the native flora of that region. In coastal areas, preserved rhizome fragments dating back 3000-4000 years have also been found in salt marsh sediments indicating that it is also native to these habitats. Native American uses of Phragmites include use of stems for arrow shafts, musical instruments, ceremonial objects, cigarettes, and both leaves and stems for constructing mats. 20 May 2005 Page 2 of 6 Plant Conservation Alliance®s Alien Plant Working Group Xeeds Hone Xild: Alien Plant Invaders of Natural Areas http://www.nps.gov/plants/alien/ Introduced Phragmites is thought to have arrived in North America accidentally, most likely in ballast material in the late 18th or early 19th centuries. It established itself along the Atlantic coast and over the course of the 20th century, spread across the continent. In Europe Phragmites is grown commercially and is used for thatching, fodder for livestock, and cellulose production. It is also declining in parts of Europe which has been of concern to natural resource managers there. Here in the United States it is not used for many purposes. BIOLOGY & SPREAD While each Phragmites plant may produce thousands of seeds annually, seed viability is typically low although there appears to be a great deal of interannual variation in fecundity. Dispersal to new sites is typically by seed except along rivers and shorelines where fragments of rhizomes may be washed down to new sites where they can establish. Along roadsides, rhizomes fragments may also be transported by heavy machinery between sites. At this time, there is no evidence for hybrid native/introduced populations occurring in the field. MANAGEMENT OPTIONS Areas with large, established, populations of Phragmites are best restored using herbicides. Other options include mowing and prescribed burning. Biological At this time no means of biological control are available in the United States for treating Phragmites infestations. Chemical Glyphosate-based herbicides (e.g., Rodeo®) are the most effective control method for established populations. If a population can be controlled soon after it has established chances of success are much higher because the below-ground rhizome network will not be as extensive. Herbicides are best applied in late summer/early fall after the plant has flowered either as a cut stump treatment or as a foliar spray. It is often necessary to do repeated treatments for several years to prevent any surviving rhizomes from resprouting. When applying herbicides in or around water or wetlands, be sure to use products labeled for that purpose to avoid harm to aquatic organisms. Fire Prescribed burning after the plant has flowered, either alone or in combination with herbicide treatment, may also be effective. Burning after herbicide treatment also reduces standing dead stem and litter biomass which may help to encourage germination of native plants in the following growing season. Plants should not be burned in the spring or summer before flowering as this may stimulate growth. Mechanical This type of control (e.g., repeated mowing) may be effective at slowing the spread of established stands but is unlikely to kill the plant. Excavation of sediments may also be effective at control but if small fragments of root are left in the soil, they may lead to reestablishment. USE PESTICIDES WISELY: Always read the entire pesticide label carefully, follow all mixing and application instructions and wear all recommended personal protective gear and clothing. Contact your state department of agriculture for any additional pesticide use requirements, restrictions or recommendations. NOTICE: mention of pesticide products on this page does not constitute endorsement of any material. CONTACTS For more information on identification and control of Phragmites, contact: • Dr. Kristin Saltonstall, Adjunct Research Scientist, Horn Point Laboratory, University of Maryland Center for Environmental Science, (914) 526-2498, ksalton at hpl.umces.edu SUGGESTED ALTERNATIVE PLANTS Native plant species that are adapted to local conditions should be used in restoration projects and as a substitute for Phragmites erosion control practices. 20 May 2005 Page 3 of 6 Plant Conservation Alliance®s Alien Plant Working Group Xeeds Hone Xild: Alien Plant Invaders of Natural Areas http://www.nps.gov/plants/alien/ How to Distinguish Native and Introduced Phragmites plants: It can be difficult to definitively distinguish native from introduced Phragmites plants without genetic testing due to the plasticity of the species and its ability to adapt to a wide range of conditions. However, a number of morphological characteristics have now been identified that can be used to determine a population’s type. These characters can be subtle (e.g. color variation) and subjective making positive identification difficult. Given this, an assignment of native or introduced status to a population should not be made unless several characters clearly match the patterns shown in table 1. Table 1: Morphological characters useful in distinguishing Native and Introduced Phragmites populations.* CHARACTER Photo NATIVE INTRODUCED Ligule width** 1.0-1.7 mm 0.4-0.9 mm Lower glume length 3.0-6.5 mm 2.5-5.0 mm Upper glume length 5.5-11.0 mm 4.5-7.5 mm Adherence of leaf sheaths** Loose – both leaves and leaf sheaths are usually dropped as the plant senesces Tight – leaves may drop off but leaf sheaths typically adhere tightly to dead stems 20 May 2005 Page 4 of 6 Plant Conservation Alliance®s Alien Plant Working Group Xeeds Hone Xild: Alien Plant Invaders of Natural Areas http://www.nps.gov/plants/alien/ CHARACTER Photo NATIVE INTRODUCED Stem color (look under the leaf sheaths, especially in places where the stem is exposed to sunlight) Summer – green to maroon, may have maroon color at the nodes only Winter – yellow to brown Summer – typically all green with yellowish nodes although some lower nodes may have maroon color Winter – yellow Stem spots Small round fungal spots MAY be present in late summer and on dead stems Extremely rare. Patches of black filamentous fungi may be seen Stem density May occur as a monoculture, often co-occurs with other plant species Typically grows as a monoculture, young newly established populations and those in areas of high salinity may be less dense 20 May 2005 Page 5 of 6 Plant Conservation Alliance®s Alien Plant Working Group Xeeds Hone Xild: Alien Plant Invaders of Natural Areas http://www.nps.gov/plants/alien/ CHARACTER Photo NATIVE INTRODUCED Leaf color Yellow-green – usually lighter than introduced Blue-green in most habitats but may be yellow-green in brackish habitats Habitat Undisturbed sites MidAtlantic – fresh to oligohaline tidal marshes Midwest – fens, marshes Highly disturbed to undisturbed sites, dominates brackish marshes along the Atlantic coast, common along roadsides throughout the U.S. * This table should not be used to distinguish between Phragmites populations along the Gulf Coast where another type of Phragmites, the Gulf Coast type, which looks similar to introduced Phragmites, is also found. ** Most reliable characters distinguishing native from introduced Phragmites. OTHER LINKS • http://www.invasive.org/search/action.cfm?q=Phragmites%20australis • http://www.lib.uconn.edu/webapps/ipane/browsing.cfm?descriptionid=85 • http://www.nps.gov/plants/alien/fact/pdf/phau1-powerpoint.pdf AUTHOR Dr. Kristin Saltonstall, Adjunct Research Scientist, Horn Point Laboratory University of Maryland Center for Environmental Science, Solomon, MD EDITOR Jil M. Swearingen, National Park Service, Center for Urban Ecology, Washington DC PHOTOGRAPHS Jil M. Swearingen, National Park Service, Center for Urban Ecology, Washington DC Dr. Kristin Saltonstall, Adjunct Research Scientist, Horn Point Laboratory University of Maryland Center for Environmental Science, Solomon MD R.E. Meadows REFERENCES Chambers, R.M., L.A. Meyerson, and K. Saltonstall. 1999. Expansion of Phragmites australis into tidal wetlands of North America. Aquatic Botany 64: 261-273. Marks, M., B. Lapin, et al. 1994. Phragmites australis (P. communis): Threats, management, and monitoring. Natural Areas Journal 14: 285-294. 20 May 2005 Page 6 of 6 Plant Conservation Alliance®s Alien Plant Working Group Xeeds Hone Xild: Alien Plant Invaders of Natural Areas http://www.nps.gov/plants/alien/ Meyerson, L.A., K. Saltonstall, L. Windham, E. Kiviat, and S. Findlay. 2000. A comparison of Phragmites australis in freshwater and brackish marsh environments in North America. Wetlands Ecology and Management 8: 89-103. Norris, L., J. E. Perry, and K.J. Havens. 2002. A summary of methods for controlling Phragmites australis. Virginia Institute of marine Science Wetlands Program Technical Report No. 02-2. Saltonstall, K. 2002. Cryptic invasion of a non-native genotype of the common reed, Phragmites australis, into North America. Proceedings of the National Academy of Sciences USA 99(4): 2445-2449. Saltonstall, K. 2003. Microsatellite variation within and among North American lineages of Phragmites australis. Molecular Ecology 12(7): 1689-1702. Saltonstall, K. 2003. Genetic variation among North American populations of Phragmites australis: implications for management. Estuaries 26(2B):445-452. Saltonstall, K. 2003. A rapid method for identifying the origin of North American Phragmites populations using RFLP analysis. Wetlands 23(4) 1043-1047. Saltonstall, K., P.M. Peterson, and R. Soreng. 2004. Recognition of Phragmites australis subsp. americanus (Poaceae: Arundinoideae) in North America: evidence from morphological and genetic analyses. Sida. Swearingen, J. 2005. Alien Plant Invaders of Natural Areas. Plant Conservation Alliance, Alien Plant Working Group. http://www.nps.gov/plants/alien/list/a.htm U.S.Department of Agriculture. 2005. Natural Resources Conservation Service Plants Database. http://plants.usda.gov/ REED CANARY GRASS (RCG) Phalaris arundinacea Reed canary grass is a very important invasive plant in Wisconsin and nearby states, and its eradication is especially difficult. It ranked #1 in importance in IPAW’s survey of invasive plants. Reproduction and Basic Ecology Reed canarygrass (Phalaris arundinacea - RCG) is a perennial, cool-season, rhizomatous plant in the grass family (Poaceae / Gramineae) that grows successfully in northern latitudes. Its creeping rhizomes often form a thick sod layer which can exclude all other plants. Its upright stems grow to 2 meters tall from the rhizomes, and its flat leaf blades measure up to 0.5 m long by 2 cm. RCG has open sheaths, hollow stems, small clasping auricles and membranous ligules. Reed canary grass can gro w on dry soils in upland habitats and in the partial shade of oak woodlands, but does best on fertile, moist organic soils in full sun. It is a major problem in natural wetlands, including marshes, wet prairies, sedge meadows, fens, stream banks, and seaso nally wet areas. It also grows in disturbed areas such as bergs and spoil piles . These stands exclude and displace desirable native plants. Areas invaded by reed canarygrass may be of little use to wildlife (Hoffman & Kearns, 1997). Human disturbance and alteration of water levels encourage reed canarygrass invasion. RCG can reproduce vegetatively by its rhizomes and rhizome fragments, as well as sexually by its abundantly produced seed. Although each inflorescence can produce approximately 600 seeds, it probably has a low successful establishment rate from seeds, especially within dense infestations. Most plants and recurring populations of RCG develop from rhizomes. RCG seeds can be dispersed in animal fur, on human clothing or on automobiles. The most common vector for RCG seeds and rhizome fragments however, is probably dispersal by water. RCG seeds have a relatively low rate of germination, and do not germinate in dense shade. Seedlings are susceptible to prolonged flooding, prolonged drought, and do not appear to be highly competitive with perennial native species. Established populations can survive prolonged drought and can survive over one year of flooding, especially if parts of the plant are not submerged. Prevention Prevention of new invasions is the most efficient and cost effective method of invasive species management and control, and the prevention of new RCG infestations are no exception to this rule. Recent research completed in Wisconsin and Minnesota have shown that when levels of available soil nutrients (such as nitrogen) are reduced via carbon enrichment, a native sedge, Carex hystericina, is able to competitively suppress the growth of RCG. Sustaining a mosaic of microtopographies (by preventing sediment accumulation) facilitates native species richness, and maintaining complex herbaceous canopies also work to prevent RCG infestation, since RCG seed germination is dependent on amounts of light penetration. Manual & Mechanical Control Methods: Digging Isolated plants or small patches of RCG can successfully be removed by digging out and removing the entire root mass. Removal is easiest when the soil is moist. Be sure to remove all rhizomes and roots, as small rhizome fragments can resprout. Properly dispose of plant material, since rhizomes and stems can develop new roots if inundated, or if kept in contact with moist ground. Be sure to follow-up to catch any resprouted stems. Mowing/Cutting Mowing or cutting (using a mower, brush cutter, weed eater, tractor-drawn mower, machete, etc.) by itself will not kill RCG. In fact, if RCG is mowed only once or twice per year, it actually stimulates additional stem production. Continued mowing (5x or more per year) for 5 to 10 years is reported as successful in controlling RCG, but this has not been demonstrated on a large scale. Mowing can be used in combination with another control method, such as a subsequent herbicide application, for good control. Additionally, mowing prior to or at the onset of flowering can eliminate seed set for that year. So, you can choose to mow RCG for several years to eliminate the seed bank, and then a final mow followed by herbicide application to eliminate mature RCG. Mowing can also facilitate the installation of shade cloth, or be used as a pre-treatment for tilla ge, since it will remove or break up the thick layer of dead litter. Tillage/Cultivation The use of large tillage machinery can successfully eliminate RCG if combined with a proper flooding regime. This method, however, requires the use of large, expensive equipment, and requires the ability to manipulate water levels. Additionally, use of tillage to manage RCG assumes that you have no species or communities of concern that you are trying to preserve at the site. If you are working in a sensitive area or in a relatively intact native system, this may not be a viable option. The purchase of the large tillage equipment (48-inch tillage plates and tractor) can be prohibitively expensive, but it may be available locally for rental or borrowing. To eliminate lar ge, dense RCG infestations using tillage + flooding, you should till through the RCG sod layer as soon as it is possible in the field season (usually, as soon as it is dry enough). The initial tillage may require several passes of the equipment, since the RCG sod layer may be thick and tough. Let the exposed stems and rhizomes dry-out. You will need to till several times during the fieldseason to break-up and dry all rhizome fragments (until you have nothing left but broken-up clods of soil). Finally, when the winter flooding begins, close floodgates and keep the entire area inundated at least 18 inches deep through late spring (late May-June) the following year. This combination of methods will eliminate large infestations of RCG, but follow-up (i.e. spot herbicide treatment with a backpack sprayer) will still be required for several years, since some RCG plants will survive or will reinvade the site. Active restoration will be necessary if a remnant seed bank does not exist. Flooding without tillage Controlling the hydrology of the site to lengthen the time an area spends totally submerged may be a viable control strategy if you have control over the hydroperiod of your site. Prescribed Fire Burning generally does not kill mature RCG, and similar to occas ional mowing, actually appears to stimulate additional stem production unless the fire burns through the entire RCG sod layer down to the mineral soil (which in turn, may create other problems). In most cases, RCG remains green long into the season, and so does not burn very hot. Herbicide treatment prior to burning can facilitate a prescribed fire, especially outside of typical “fire seasons.” Prescribed fire can however, be used as a pretreatment to tillage, shade cloth, or prior to herbicide application for good results, since the fire will remove the aboveground dead litter and standing vegetation. Burning for several years in a row is generally not possible because of lack of fine fuels after the first-year burn. Solarization, Shade Cloth, & Mulching Solarization (essentially baking under clear or black plastic) or the use of a thick woven geotextile shade cloth can be used to eliminate RCG. In dense areas of patchy RCG growth, this method can provide specific, targeted control . In areas where RCG is mixed-in with desirable species, the kill of those desirable species may or may not be an option. Also, the use of certain materials for this method depends on your overall management goals. Excellent control of RCG can also be accomplished by using a thick woven plastic fabric (Mirafi(r) or Amoco(r) brands), held in place by 7-inch gutter spikes and washers and duck-bill tree anchors. The fabric is kept in place for over one year (over an entire growing season), even under inundation. This method will kill all plants under the cloth. Revegetation or reseeding is generally necessary with this method. Shade cloth is initially expensive (approximately $400 per 12 ft x 350 ft roll), but can be reused several times, and this method does not require follow-up vis its during treatment. Mowing prior to the installation of shade cloths greatly facilitates installation. Small patches can likely be treated using black plastic bags, if they are kept in place for the entire duration, the edges are tacked-down firmly, and the bags do not shred. Grazing Grazing may be effective means for controlling reed canarygrass but the palatability of RCG is questionable--the genus Phalaris is notoriously unpalatable and an illness associated with the affects of consumption is called ‘Phalaris staggers’ (Marten et al., 1976). Cattle prefer RCG when stems and leaves are young and succulent, but do not prefer it once stems become old and tough. Goats and sheep will graze on RCG. Grazing can be combined with another treatment method (follo wed by tillage, herbicide, shade cloth), for good control. Grazing can also be inappropriate in wetland settings (Hutchison, 1992). Biological Control There are no known biological control agents for RCG. Chemical Control Methods RCG can be successfully controlled by the proper use of herbicide. Small stands or clumps of RCG can be effectively killed with one application, but large infestations will likely require applications over several years to be effective. Since RCG frequently grows in wet areas, only herbicides approved for aquatic habitats are allowed in many situations. As with all herbicide use, be sure to read and follow all label instructions and to abide by all state regulations. Glyphosate (Rodeo®, Aquamaster®, or Glypro® among others) applied in a 2% solution (1.08% active ingredient (a.i.)) with a nonionic surfactant works well to kill RCG. Glyphosate (Rodeo) is a non-selective herbicide that kills or injures nearly all plant species. Glyphosate is also available in many other formulations (e.g. RoundUp®). These work well to kill RCG, but are not labeled for aquatic use, so be aware of the areas where you plan on applying herbicide. Sethoxydim (Vantage®) is a grass-specific herbicide that has been used to kill RCG with some success, but it is also not labeled for aquatic use. Depending on the size and distribution of your infestation, the herbicide can be foliar-applied using a dripless wick applicator, backpack sprayer, or boom sprayer. Herbicide should be applied to foliage during the growing season. Application can occur in mid-summer (just prior to summertime dormancy) or preferably in late fall (just prior to frost and wintertime dieback). It is recommended to apply herbicide at these times, since it is speculated that these are the times of year when RCG is most actively translocating carbohydrates (along with the herbicide) down into the root system. You may also combine an herbicide treatment with another control treatment for good results. First, eliminate the aboveground dead litter by mowing or burning, then allow the RCG stems and leaves to regrow to boot height. This helps obtain better herbicide coverage and reduce total herbicide use, since you are spraying only living green RCG that is 12" tall vs. 6' tall stems mixed with old dead leaves. Follow-up monitoring and treatment is necessary for several years to ensure complete kill. Restoration/Competition Planting fast-growing shrubs or trees may eventually eliminate RCG since it is intolerant of year-round shade, but depending on yo ur management goals and objectives, this may not be a viable option. Best Management Practice Recommendation The best management approach to use will depend on your overall management goals and objectives, the size, distribution and location of your RCG infestation(s), your capability and willingness to use herbicides (or not), and your available resources (staff and volunteer time, money, equipment, etc). The following recommendations are not necessarily the best management methods for every situation, nor are they presented in an order of preference. The methods listed below have however, been used with some success. Also, every method will require follow-up monitoring and treatment (including replanting native species if necessary) to ensure the long-term success of your treatments. Scattered individual plants or small patches in healthy native vegetation 1. Dig out using a shovel 2. Spot-spray or wick with herbicide 3. Spot flame with a propane torch (only works for seedlings or young individuals) Distinct patches of RCG within a matrix of native vegetation 1. Dig out using a shovel (depends on size) 2. Cover with shade cloth (may be preceded by mowing) 3. Mow (to eliminate seeds), then spot-spray or wick with herbicide 4. Spot-spray or wick with herbicide Large patches (up to several acres) of RCG with scattered native vegetation (Which method you choose will depend on how much you want to keep your native vegetation) 1. Mow then cover with shade cloth 2. Mow then herbicide (wick, spot-spray or boom) 3. Herbicide using appropriate application technique 4. Spot-burn then spot-spray regrowth 5. Cover with shade cloth (may be preceded by a mow treatment) Large (hundreds of acres) monocultures of RCG 1. Mow using large mower, herbicide spray using boom spraye r 2. Prescribed burn, then herbicide spray using boom sprayer 3. Tillage and flooding Summarized below are references to papers providing more detail. Mandy Tu, Ph.D., works with the Invasive Species Intiative of The Nature Conservancy, Oregon Chapter. Her PowerPoint presentation chronicles the comparison of various control efforts in Oregon. (5.4 MB) Download now. For a quick look at the results of the study, here's a single PowerPoint slide (53 KB): Download now. The following is the now published paper discussing the study: Controlling Phalaris in the PNW Authored By: Mandy Tu, The Nature Conservancy's Wildland Invasive Species Team The report by Galatowisch and Reinhart (UMn) on best management practices for reed canary grass can now be downloaded/printed from the U.S. Shorebird Conservation Plan website at: http://shorebirdplan.fws.gov/USShorebird/ManagementReports.htm RCG= Reed canarygrass N=Nitrogen * For a discription of growth stages see the bulletin, Growth and Staging of Wheat, Barley and Wild Oat at http://plantsci.missouri.edu/cropsys/growth.html Treatment Effect Should use Could use Should not use Comments Burning • Removes biomass and litter; might kill seeds on soil • Reduces available N over multiple burns (N volatilized) • Seed bank released, both desirable/undesirable species • Stimulates dormant buds of RCG, rhizomes re-sprout • Can jumpstart growing season by warming soil • To reduce RCG in late spring after RCG is active but before natives break dormancy • To force RCG to re- sprout and use reserves from rhizomes • Use in combination with other practices • To remove thatch prior to a planting/seeding of desirable natives • To remove thatch and prompt early spring sprouting of RCG, which can then be treated with glyphosate or sethoxydim • In fall to control RCG in short term, because RCG benefits from high light conditions that follow fire • In early spring in mixed vegetation sites, because RCG growth will be encouraged by increased light, unless you plan to combine with another treatment • On organic sites when very dry • Jumpstart occurs if burn done in fall or spring • No research on critical density of RCG that can be controlled by burning alone • Early burns will stimulate RCG; timing and frequency critical Excavation • Removes rhizomes and seed bank • Removes sediment and nutrients • Alters hydrology • Where material can be pushed to fill drainage ditches or where it can be moved off site; where deeper water is desired • During winter, to reduce soil compaction • During summer when wet sites are dry • To remove alluvium over native wetland soils • If there is no soil disposal site. • If compaction is an issue • If you don’t want a deep-water marsh. • If there is a high-quality remnant plant community in area • May cause soil compaction • RCG will rapidly re-colonize disposed soil; use caution when selecting a disposal site • Additional treatments will be necessary on drier sites • Seed with natives afterwards, except in the deepest water, or if a rich native seed bank exisits • May require special permits Tree/shrub planting • When woody species overtop RCG, shade slows its growth • May change plant community • Adds structure to habitat • Where herbaceous vegetation cannot gain a competitive advantage • In an area where landscape is receiving RCG seed inputs • Where inflows can’t be diverted • To connect existing woody patches • Where management goal is to maintain grassland habitat • Need to apply herbicide/mulch around newly planted trees/shrubs • Conifers may be the most effective at shading RCG • Need to control RCG for 3-5 years to allow trees to establish • Shelter tubes may be cost-effective Grazing • Reduces biomass in spring • Causes disturbance • Allows seedling establishment (good/bad) • Adds nutrients to system • In highly disturbed sites to reduce RCG biomass • In fall, after a prescribed burn (RCG regrowth more palatable) • To reduce biomass and height before herbicide treatment • To reduce seed production • Lightly, to sustain diversity • During wet conditions in spring where trampling and compaction can damage a site • On high quality sites • Once started, cannot stop, unless you switch to another treatment • Not an effective practice alone • Use proper stocking rates to prevent overgrazing of desirable species Mowing & harvesting (haying) • Removes biomass and nutrients that are accumulated in biomass • Directly damages RCG • Similar effects to fire (promotes seed establishment, stimulates plant growth by increasing light) • To reduce biomass before herbicide treatment • To remove P from site • Before seed heads appear (boot to late boot)* • To prepare for RX fire • To prepare for herbicide application • As a substitute for fire (though not quite the same) • To change fire behavior • Where tussocks and microtopography will be damaged • If grassland bird habitat will be impacted. • When site is too wet for equipment • On high quality sites, avoid use during growing season • Mow before RCG seed heads appear (boot to late boot stage)* Mowing without harvesting • Reduces plant height • Increases light—promotes competition • Depletes rhizome reserves • Creates dry biomass for fire • To prepare for RX fire • To prepare for herbicide application • To stress RCG • When harvesting equipment is not available • To change fire behavior • Where tussocks and microtopography will be damaged • If grassland bird habitat will be impacted. • When site is too wet for equipment • Mow before RCG seed heads appear (boot to late boot stage) • Could impede establishment of natives, due to remaining mat of vegetation Herbicide: glyphosate • Reduces plant height • Increases light—promotes competition • Depletes rhizome reserves • Creates dry biomass for fire • On sites without native plants prior to reseeding. • To dry out RCG in order to burn • In late summer for maximum translocation to roots • For treating clones within areas of desirable natives • As an initial herbicide treatment on monotypic stands of RCG • Where RCG height precludes use of other herbicides • In early spring or late fall, when RCG is live, but other plants dormant • On wet sites, use Rodeo® • On sites with desirable native plants actively growing • Where desirable plants are intermixed with RCG • Soon after mowing/burning • When amphibians are on site (Roundup® surfactant has negative effects) • Should be part of a continued control strategy, where natives would be later introduced • Multiple treatments may be necessary • May need a permit for application on wetlands • Translocation ineffective when temperature is >70º F • Other herbicide/mowing treatments may influence herbicide effectiveness • Add ammonium sulfate to tank mix if water is hard Herbicide: grass- specific (i.e. sethoxydim or fluazifop) • Suppresses growth of most perennial grasses • Releases native plant community (except for grasses) • On sites with desirable, native, non-grass species • When active growth resumes after burning/ mowing, when RCG is 6-12” tall • Following other herbicide treatments to control residual or re- emerging RCG • To obtain immediate eradication • If standing water is present • On high quality sites with desirable grasses • When RCG is >12” tall • Apply with surfactant or crop oil • Apply when temperature >70º F (better rhizome translocation) • > one treatment required • Effectiveness of sethoxydim is reduced by UV light • Add a water conditioner or acidifier if water is hard Tillage • Exposes rhizomes to light; might activate dormant buds • Slices rhizomes • Can contribute to erosion • To prepare site for herbicide by making more rhizome buds responsive to chemical control • On monotypic, damaged sites to prepare for crop production • To prepare a seedbed • To reduce RCG seed bank • Where microtopography needs to be maintained. • Where desirable natives are mixed with RCG • On wet sites, where soil could become compacted, or equipment can get stuck/damaged • Where offsite impacts are possible (sedimentation/erosion) • Need to combine with another treatment, or repeat tillage • Depth should be 4-6” to target RCG rhizomes • Spring or early summer tilling preferred • Could till every four weeks during growing season, depending on management goal Altering hydrology • Prolong/increase water levels • Prevents RCG seed germination • Kills RCG rhizomes • If new water depth is > 12” • If high water can be maintained through the growing season. • To promote the growth of emergent plants such as native cattail, burr-reed and bulrush species • If new water depth is < 12” or site seasonally dries out • If other invasives are nearby (Typha x glauca, Phragmites) • Effects vary by site • High water can promote growth of other invasives (Typha x glauca, Phragmites) if present in the area • Can be combined with tillage • May require special permits Mulching / solarization with plastic or fabric • Non-selective treatment; shades out all plants • Kills adult plants • Kills RCG rhizomes • For small, isolated RCG clones • For 1-3 consecutive years • On patches with high edge:area ratio, to facilitate recolonization by soil fauna • To facilitate seeding or planting of natives • Where desirable natives are mixed with RCG • For abatement on large sites • If native species are present • In areas with microtopography • Resurgence from seedbank may occur when tarping removed • May have adverse effects on soil microorganisms • May alter soil chemistry • Not always an effective treatmentDRAFT Reed Canarygrass Control Practices: Effects and Management RecommendationsA reference table for landowners and restoration professionalsAlthough the recommended reed canarygrass control practices are based on advice from experienced practitioners and researchers, they have not been fully tested in a field setting. Following recommendations from this table does not guarantee control and/or eradication of reed canarygrass. Site-specific conditions and timing variables are likely to influence results. When applying chemical herbicides, be sure to follow all safety precautions and label recommendations. Over-application or unintended use of pesticides can potentially harm the environment and pose a safety risk to the user. Controlling reed canarygrass may result in other invasive or undesirable species attempting to colonize the site after suppression of the reed canarygrass. Follow-up monitoring or control of other invasives may be needed. When tractors, mowers, or bulldozers are used in reed canarygrass control, be aware of the potential to pass on seeds, rhizomes or other plant parts to new locations unless equipment is cleaned after use. Federal, state and local permits may be required when performing restoration work in wetlands or along waterways. Contact your local DNR office or county zoning administrator before initiating reed canarygrass control work. A few things to remember... Contributors: Craig Annen, Tom Bernthal, Thomas Boos, Mike Casler, Judy Derricks, Jerry Doll, Patricia Haack, Mike Healy, Rich Henderson, John Jackson, Kelly Kearns, Greg Kidd, Art Kitchen, Rhonda Krueger, Matt Otto, Pat Trochlell, Robert Weihrouch, Julia Wilcox and Joy Zedler This publication is part of an ongoing effort to sythesize and develop effective means of controling invasive reed canary grass in natural areas. For more information, contact: Art Kitchen Wisconsin Private Lands Office 4511 Helgesen Drive Madison, WI 53718 (608) 221-1206 x 13 (office) e-mail: art_kitchen@fws.gov Design funded by EPA Wetland Protection Grant #: CFDA #66.461 under Wisconsin DNR contract NME00000830 First printing, January 2006 Please cite as: Wisconsin Reed Canarygrass Management Working Group. 2006. Reed canarygrass control practices: effects and management recommendations