HomeMy WebLinkAboutFORT COLLINS NISSAN-KIA - PDP210017 - SUBMITTAL DOCUMENTS - ROUND 3 - WETLANDS DOCUMENTS
937 Mallard Drive, Ft. Collins, CO 80521 • (970) 224-0851 • www.bluemountainenvironmental.com
April 13, 2022
Cathy Mathis, APA
TB Group
444 Mountain Avenue
Berthoud, CO 80513
RE: Fort Collins Nissan-Kia Revised Wetland Restoration Plan
Ms. Mathis:
This restoration plan is intended to be used for revegetation of two areas at Fort Collins Nissan-
Kia: 1) wetlands within Detention Ponds and 2) Bioretention Areas. The approximate locations
of these areas are illustrated on the Fort Collins Nissan-Kia Overall Grading Plan dated
10/6/2021 (here incorporated by reference). Areas to be restored occur principally on the
southwestern portion of the proposed development.
Our recommended approach for these two areas includes soil treatment, planting native
vegetation, erosion control, irrigation, noxious weed management, and maintenance.
Recommended restoration activities, as well as success criteria, are outlined on the following
pages. This plan was prepared by Craig Severn, Amy Randell and Matt Tobler.
Feel free to contact me with questions.
Sincerely,
Matt Tobler
Natural Resource Specialist, Certified Ecologist
Blue Mountain Environmental Consulting, LLC
Ft. Collins Nissan – Kia
Wetland Restoration Plan
Wetland Restoration Plan
This wetland restoration plan outlines treatments for the bottom and lower side slopes of the
proposed detention ponds and bioretention areas (as identified on the Site Plan dated 10/6/2021).
Note: This wetland restoration plan excludes areas immediately adjacent to bioretention
swales as this area is include in the Upland Revegetation and Restoration Plan. The actual
timing of project implementation is unknown, so only general temporal guidelines are provided.
This plan includes guidelines for soil treatment, erosion control, planting wetland vegetation and
site maintenance. This restoration plan assumes that water sufficient to support hydrophilic
plants will be present, but future water availability is unknown. Table 1 below outlines
restoration activities for each year.
Table 1. Summary of restoration activities for Detention Pond and Bioretention Areas at Fort
Collins Nissan-Kia.
Year Reference
Section
Detention Pond Bioretention Area
1
early
Soil Treatment Grade and stockpile
approximately 55 to 60 cubic
yards of wetland topsoil from the
existing unnamed wetland (west
of Venus Avenue).
N/A
1
early
Plant Topsoil
Piles if
Necessary
Seed with sterile triticale or native
seed mix depending on storage
period.
N/A
1
spring-
summer
Irrigation Irrigate topsoil piles if necessary
to promote seed germination and
plant growth.
N/A
1
summer
Grading/Topsoil
Addition
Establish a gentle gradient profile
through bottom of pond area.
Add 6 inches of wetland topsoil to
graded bottom.
Establish a profile through bottom of
pond area. Add 6 inches of course
textured soil to graded bottom and
allow to settle.
1
late fall
Plant Native
Seed Mix(s)
Drill or broadcast wetland seed
mix into firm seed bed on pond
bottom in late fall to early spring.
Seed pond side slopes with
upland native seed mix.
Drill or broadcast sandy soil seed
mix into firm seed bed in late fall to
early spring.
1
After
seeding
Mulch
Application
All seeded areas will be mulched
within 24 hours of seeding.
Install Rolled Erosion Control
Products (RECP) on slopes 3:1 or
steeper.
All seeded areas will be mulched
within 24 hours of seeding. Install
Rolled Erosion Control Products
(RECP) on slopes 3:1 or steeper.
1 Wetland Plugs Order 10 cubic inch wetland plugs N/A
Ft. Collins Nissan – Kia
Wetland Restoration Plan
late for spring planting.
2
spring
Wetland plugs Plant wetland plugs to deep, mid,
and shallow planting zone areas.
N/A
2-4
spring-fall
Monitoring and
Maintenance
Monitor seeded areas for weeds,
irrigation needs, erosion, and bare
areas. Implement need
maintenance.
Monitor seeded areas for weeds,
irrigation needs, erosion, and bare
areas. Implement need maintenance.
2-4
spring-
summer
Irrigation Irrigate if necessary to promote
plug growth and seed
germination and plant growth.
Irrigate if necessary to promote seed
germination and plant growth.
2
summer
Noxious and
Annual Weed
Control
If annual weeds are present, mow
monthly with mowing heights no
less than 4 to 6 inches. Manage
noxious weeds.
If annual weeds are present, mow
monthly with mowing heights no less
than 4 to 6 inches. Manage noxious
weeds.
3-5
summer
Noxious and
Annual Weed
Control
If annual weeds are present, mow
monthly with mowing heights no
less than 10 inches. Manage
noxious weeds.
If annual weeds are present, mow
monthly with mowing heights no less
than 10 inches. Manage noxious
weeds.
5 Determine
Success Criteria
Determine if success criteria for
vegetative cover has been met. If
success criteria have not been met,
maintain growth for additional
year.
Determine if success criteria for
vegetative cover has been met. If
success criteria have not been met,
maintain growth for additional year.
Year 1 Early – Soil Treatment
Detention Ponds
Retain wetland topsoil displaced by grading operations from the unnamed wetland west of Venus
Avenue and stockpile topsoil for distribution on the bottom of the detention ponds. Stockpile
topsoil away from all drainage system components including swales and storm-sewer inlets.
Where practical, choose stockpile locations that that will remain undisturbed for the longest
period of time as the phases of construction progress. Place sediment control structures around
the perimeter of the topsoil stockpile. This may include sediment control logs, rock socks, silt
fence, straw bales or sand bags. Soil stockpiles shall not exceed 10 feet in height to preserve soil
microbes that will aid in plant establishment (Urban Drainage and Flood Control District, 2016).
Stockpiles shall be kept loose, not compacted, and watered as needed to prevent dust migration.
Additional stockpile management practices are provided in the Fort Collins Stormwater Criteria
Manual dated September 2018. Avoid piling anything, including subsoil, construction debris,
etc., on the topsoil stockpile. Avoid handling topsoil when it is wet. Store upland and wetland
top soils in separate piles. Stockpiles should be monitored for signs of erosion displacement and
sediment accumulation and, if conditions warrant it, stockpiles shall be structurally covered if
stored less than 30 days.
Ft. Collins Nissan – Kia
Wetland Restoration Plan
Year 1 Early – Plant Topsoil Piles if Necessary
Detention Ponds
If topsoil is not going to be redistributed within 30 days within one growing season, plant a cover
crop on the topsoil stockpile. We recommend QuickGuard Sterile Triticale to minimize
colonization of non-native species. Broadcast QuickGuard Sterile Triticale at a rate of 40 pounds
pure live seed (PLS) per acre followed by raking to incorporate seed into soil to a depth of ½ to
¾ inch. Seeding should be conducted after May 15 or after the last frost. Cover with weed-free
straw mulch or hydro mulch. Seed in anticipation of precipitation or during winter when soils
are not frozen. If soil is to be stored for more than one growing season, seed with a native
prairie seed mix presented in Table 2 of the Upland Restoration Plan. The seed mix may be
purchased from Pawnee Buttes Seed Company, Arkansas Valley Seed, or Western Native Seed.
Year 1 Spring, Summer – Irrigation
Detention Ponds
If dry conditions persist after seeding the wetland topsoil stockpile, sprinkler irrigation may be
necessary for successful seed germination. If dry conditions exist during the growing season,
irrigation may be necessary for adequate plant establishment.
Year 1 Summer – Grading/Topsoil Additions
Detention Ponds
In the lower portions of the detention basin restoration areas where wetland seed and plugs are to
be planted, a gentle gradient profile across the basin will be established to provide for deep, mid,
and shallow planting zones. The deep zone will represent 0.01 acres, mid zone 0.03 acres, and
the shallow zone 0.03 acres in size. There should be approximately 1.5 feet elevation difference
between the deep and shallow zones. When grading and contouring operations are complete,
distribute approximately six inches of wetland topsoil to the bottom of detention ponds and allow
to settle. Excess topsoil should extend evenly up the sides of the contoured bottom.
Bioretention Areas
Following application of coarse textured soil to the bottom of the bioretention areas, allow soil to
settle (ideally with rainfall) for 7 days prior to seeding (Urban Drainage and Flood Control
District, 2016; Shaw, 2018). At the time of seeding, a human footprint should compact the soil ¼
to ½ inch. Soil compaction with a cultipacker is not recommended on clay/loam soils because
this treatment will result in soils that are too firm (Urban Drainage and Flood Control District,
2016).
Year 1 Late Fall – Plant Seed Mixes
Detention Ponds
Restoration activities within detention ponds shall result in establishment of at least 0.07 acres of
wetland to satisfy City of Ft. Collins requirements. Once the soil is settled, seed prairie wetland
mix (as described in Table 2) from Pawnee Buttes Seed Inc. Seed should be planted with a
native-grass-seed no-till drill at 10 pounds PLS per acre to the bottom on the detention ponds.
Alternatively, broadcast seed with a Chapin® Professional Bag Seeder at double the rate (20
pounds PLS per acre) and rake into the soil. In either case, seed depth should be about ⅛ to ¼
Ft. Collins Nissan – Kia
Wetland Restoration Plan
inch into the soil in row 7 to 12 inches apart. The site should be seeded in late fall (after October
15) to allow seeds to naturally stratify over winter. Seeding is not recommended between June 1
and October 15. Provide adequate temporary irrigation for establishment of seeded areas as
discussed in the section Maintenance of Seeded Area. Seed in anticipation of moisture or during
the winter when soils are not frozen.
Apply upland native seed mix (see Table 2 Upland Restoration Report) on adjacent upland side
slopes per Upland Ecological Restoration Guidelines after wetland species are seeded on the
bottom of the detention pond. Final drilling pass must occur on the contour, to create subtle
ridges perpendicular to the flow of energy. If seed is broadcast on side slopes, a bulldozer may
be used to compress seed into the soil. This step is not necessary if uplands are seeded with a
no-till drill. This will encourage plant establishment on side slopes and provide extra erosion
control. Native grass seed mix will need to be applied prior to placing Rolled Erosion Control
Products on slopes 3:1 or steeper. All seeded areas on the upland sideslops shall be mulched
within 24 hours of seeding, and the mulch shall either be adequately crimped and or tackified.
Table 2. Pawnee Buttes Seed Company Prairie Wetland Mix for planting in the Detention Pond
basins. Recommended seeding rate is 10 pounds per acre.
Common Name Scientific Name Growing Zone
Canada wildrye Elymus canadensis Shallow
Switchgrass Panicum virgatum Shallow
Prairie cordgrass Spartina pectinate Shallow
Baltic rush Juncus balticus Shallow
Nebraska sedge Carex nebrascensis Mid
Creeping spike rush Eleocharis palustris Mid
Three square bulrush Schoenoplectus pungens Mid
Wooly sedge Carex pellita Mid
Alkali bulrush Bolboschoenus maritimus Deep
Soft stem rush Schoenoplectus tabernaemontani Deep
Hardstem bulrush Schoenoplectus acutes Deep
Bioretention Areas
Once the soil is settled, seed a sandy soil native seed mix (as described in Table 3). Confirm the
size of the area to be seeded. Seed should be planted with a no-till grain drill at 10 pounds PLS
per acre on the bottom of the bioretention areas. Alternatively, broadcast seed with a Chapin
Professional Bag Seeder at double the rate (20 pounds PLS per acre) and rake into the soil. In
either case, seed depth should be about 1/8 to 1/2 inch. The site should be seeded in late fall
(after October 15) to allow seeds to naturally stratify over winter. Seeding is not recommended
between June 1 and October 15.
Table 3. Sandy soil seed mix for bioretention areas.
Common Name Scientific Name PLS/lb. PLS lbs/ac PLS/SF
Ft. Collins Nissan – Kia
Wetland Restoration Plan
Switchgrass Panicum virgatum 389,000 0.80 7.1
Indiangrass Sorghastrum nutans 175,000 1.10 4.4
Sideoats grama Bouteloua curtipendula 190,000 1.50 6.5
Sand dropseed Sprobolus cryptandrus 5,200,000 0.06 7.2
Prairie sandreed Calamovilfa longifolia 273,000 1.16 7.3
Big bluestem Andropogon gerardii 130,000 0.90 2.7
Little bluestem Schizachyrium scoparium 260,000 0.90 2.7
Sand bluestem Andropogon hallii 113,000 0.80 2.1
Western wheatgrass Pascopyrum smithii 110,000 0.70 1.8
Indian ricegrass Achnatherum hymenoides 141,000 2.10 6.8
Weeping Alkaligrass Puccinellia distans 1,669,000 1.8 7.0
Inalnd Saltgrass Distchlis stricta 600,000 0.42 5.0
Alkali Sacaton Sporobolus airoides 1,750,000 0.10 4.2
Total 10.23 64.8
Year 1 – Mulch Application
Detention Ponds and Bioretention Areas
We assume that site activities will include all appropriate erosion control methods as determined
by the project engineer to control erosion within drainage ditches, culvert outlets and on side
slopes within 24 hours of seeding. Apply weed-free straw mulch to seeded areas at a rate of 2
tons per acre with 50 percent of the straw by weight should be 10 inches or more in length.
Spread straw uniformly over seeded areas and crimp into the soil. Avoid spreading mulch when
wind is in excess of 10 miles per hour. Hydro mulch application is also suitable. We
recommend Rolled Erosion Control Products (RECP) on slopes 3:1 or steeper. It is best to avoid
thick straw or excelsior blankets because they can impede grass establishment. It is
recommended to use only biodegradable RECPs, such as coconut straw composite blankets or
jute netting, because plastic netting may trap snakes, deer and other wildlife that may utilize the
area. RECPs must be installed correctly to be effective such as preparing the soil, seeding before
it is placed and placing in accordance with the manufacturer’s recommendations (Urban
Drainage and Flood Control District, 2016).
Year 1 Late – Order Wetland Plugs
Detention Ponds
Following the seed application, plant wetland plugs. Ten (10) cubic inch cone plugs should be
pre-ordered from Aquatic and Wetland Nursery, LLC in Fort Lupton, CO to insure availability at
time of spring planting. Refer to Table 4 for specific species and quantities.
Table 4 Wetland species list and quantities for 10 cubic inch cone plugs to be planted in deep,
mid, and shallow zones located in the detention basin restoration areas.
Common Name Scientific Name Planting Zone Amount
Baltic rush Juncus balticus Shallow 145
Ft. Collins Nissan – Kia
Wetland Restoration Plan
Inland saltgrass Distichlis spicata Shallow 145
Nebraska sedge Carex nebrascensis Mid 194
Creeping spike rush Eleocharis palustris Mid 194
Threesquare Schoenoplectus pungens Mid 194
Hardstem bulrush Schoenoplectus acutus Deep 194
Total 1,066
Year 2 Spring – Plant Wetland Plugs
Detention Ponds
Plant plugs in spring after May 15 or after the last frost when soil temperature is above 65° F.
Deep, mid, and shallow planting zone areas representing 0.01, 0.03, and 0.03 acres respectively,
will be established and then planted to the corresponding species as shown in Table 4. Use a
shovel or hand-held digging tool to open a hole slightly deeper than plug, insert plug and firm
soil around plug. Evenly space plugs throughout the wetland in the appropriate planting zone on
18 inch centers. Be mindful of trampling if wetland seed mix was dispersed in the fall. If seeds
were not planted in the fall, broadcast seed after plugs are planted to reduce trampling.
Year 2-4 – Monitoring and Maintenance
Detention Ponds and Bioretention Areas
Seeded and plugged areas shall be monitored several times a year for three or more years to
ensure that success criteria will be met. Monitoring may require that adaptive management be
employed as site conditions dictate. Conditions affecting the timing and frequency for
monitoring include temperature, precipitation, plant phenology, timing of site activities, etc.
Monitoring will include the following: presence and abundance of weeds; irrigation needs;
erosion issues; and bare areas needing reseeding. Site conditions shall be communicated to the
project team with appropriate action(s) taken as necessary. Weed issues should be addressed,
irrigation shall be provided as seasonal trends dictate, additional erosion control measures may
also be necessary, and bare areas should be reseeded.
Year 2-4 spring-summer – Irrigation
Detention Ponds
Water management is critical during wetland plant establishment, remaining crucial throughout
the life of a wetland (Hoag & Tilley, 2007). If seeds are planted in fall, then irrigation will not be
necessary until spring of next year. If dry conditions are present in the spring after wetland plug
planting, irrigation may be necessary for successful plug establishment and wetland seed mix
germination. During early plant establishment, seedling roots are near the surface and benefit
from frequent, short irrigation periods (Urban Drainage and Flood Control District, 2016). For
native seed to germinate, the top 1-2 inches of soil should be moist, but not saturated, (Urban
Drainage and Flood Control District, 2016). Complete inundation of most plant species during
germination can be lethal (Hoag & Tilley, 2007). Once plants are established, decrease irrigation
Ft. Collins Nissan – Kia
Wetland Restoration Plan
frequency to 3-4 days per week (too frequent irrigation can encourage shallow rooting; Urban
Drainage and Flood Control District, 2016) and increase duration, allowing moisture to reach a
depth of up to 6 inches in the soil. Once seeded plants are established, irrigation should be
decreased to 2 days per week from late summer until the fall when irrigation should cease (Urban
Drainage and Flood Control District, 2016). It is recommended to irrigate early in the morning
(before sunrise) or in the evening (before sunset) to conserve water during the growing season
and to prevent fungal diseases. Refer to Table 5 for a sample irrigation schedule.
In the event that sufficient precipitation during the period of plug establishment and seed
germination occurs naturally, then the irrigation schedule can be suspended until drier condition
exist and irrigation is needed.
Table 5. Recommended irrigation schedule for Detention Ponds.
Time of Year Frequency
Morning
Water
Evening
Water
Soil Moisture
Depth (inches)
Mid-April to mid-May
1-2x/day until avg.
temp is 80º F 1x 1x 2
Early June to July
Every other day, if
avg. temp is 90º F then
1x/day 1x 0 6
July to mid-August 1x/week 1x 0 6
Mid-August to mid-
September 1x every other week 1x 0 6
Mid-September to
April
Withhold watering to
allow plants to harden
for winter 0 0 0
Bioretention Areas
If dry conditions persist in the spring after seeding, sprinkler irrigation may be necessary for
successful seed germination. If dry conditions exist during the growing season, irrigation may be
necessary for adequate plant establishment and growth. Assuming that the project is seeded in
fall or early spring, irrigation shall be initiated in the first year after planting after springtime
moisture is no longer available. Seeded areas shall be irrigated in the morning once per day until
seed have germinated and grown past the three leaf stage. Irrigation shall be sufficient to
moisten the top 1-2 inches of soil without generating runoff. Irrigation shall continue throughout
the first summer and fall after planting at a rate of two to four times per week depending on site
conditions. Irrigation will likely be necessary one to three times per week in the summers of
year three and four.
Year 2 Summer– Noxious and Annual Weed Control
Ft. Collins Nissan – Kia
Wetland Restoration Plan
Detention Ponds and Bioretention Areas
If annual weeds are present, mow monthly with mowing heights no less than 4 to 6 inches. Use
of a narrow blade spade shovel for removing large tap roots, hand pulling, or spot herbicide
application via a wick or spray applicator can be used to control other undesirable species as
necessary. Digging or hand pulling undesirable plants when soil is moist will be the most
effective means of control provided sufficient labor is available. Apply spot-control herbicide
with a hand-held, backpack sprayer or wick applicator. Spot control of Canada thistle is
especially important during early plant establishment as this noxious weed species can be
aggressive during early plant establishment and is difficult to control once it has become
established. Areas where soils are commonly saturated or moist are conducive to Canada thistle
invasion.
Herbicide application is to be conducted by a licensed commercial applicator. It is important note
that many herbicides are toxic in aquatic ecosystems and may cause significant risks to human
health. Herbicides can enter water-bodies either directly through spray or spray drift, or they can
move into water-bodies via surface water run-off or leaching and sub-surface draining.
Herbicides used in and around wetland areas should be labeled for use in wetland areas.
Several State-listed noxious weed species are present on the property and should be actively
managed to prevent their establishment in restored areas including leafy spurge (Euphorbia
esula), musk thistle (Carduus nutans), Dalmatian toadflax (Linaria dalmatica), field bindweed
(Convolvulus arvensis), and mullein (Verbascum thapsus). Other undesirable species include
cheatgrass (Bromus tectorum), kochia (Bassia scoparia), Russian thistle (Salsola iberica),
yellow salsify (Tragopogon dubius), prickly lettuce (Lactuca serriola), yellow sweet clover
(Melilotus officinalis), pennycress (Thlaspi arvense), and flixweed (Descurainia sophia).
Noxious weed management guidelines are provided in Appendix A.
Years 3-5 – Noxious and Annual Weed Control
Detention Ponds and Bioretention Areas
If annual weeds are still present, mow monthly with mowing heights no less than 10 inches. Use
methods described in Year 2 above to control noxious and other weeds.
Year 5-6 – Measure Success Criteria
Detention Ponds and Bioretention Areas
Success criteria for security release is detailed in the Development Agreement (DA), which is
specific to each project. The standard success criteria is 70% average vegetative cover with less
than 10% cover of noxious weeds and no bare ground areas greater than 1 square foot. Cover
requirements are expected to be achieved within three to five years after planting the native seed
mix under normal growing conditions of temperature and natural moisture.
Monitoring and Maintenance
Seeded areas shall be monitored several times a year for three or more years to ensure that
success criteria are met. Monitoring and adaptive management shall be employed as site
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Wetland Restoration Plan
conditions dictate. Conditions affecting the timing and frequency of site visits include
temperature, precipitation, plant phenology, timing of site activities, etc. Site conditions shall be
communicated to the project team with appropriate redirection taken as necessary. Bare areas
should be reseeded, additional erosion control measures may also be necessary and irrigation
shall be provided as seasonal trends dictate. Monitoring results shall be communicated to the
project manager who will inform the City of Ft. Collins regarding on the ground conditions and
adaptive management strategies.
Ft. Collins Nissan – Kia
Wetland Restoration Plan
Appendix A: Noxious Weed Management
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Wetland Restoration Plan
Canada Thistle
Cirsium arvense is an exotic perennial forb that can
spread by seed, but is more of a problem due to its
ability to spread rapidly from vigorous rhizomes that
can extend 15 feet from the parent plant and 6-15
feet deep (Beck 2013). It is an erect plant that can
grow up to 5 feet tall. Flowers are small, ranging
from white to deep purple. Leaves are usually
deeply incised with spiny margins. Infestations often
begin on disturbed sites such as ditches, overgrazed
pastures, or waste areas (Beck 2013). Canada thistle
is a problem weed in riparian areas, but is also found
in upland sites. Seeds are able to germinate within 8
to 10 days of pollination. Canada thistle begins
growth as a rosette from mid-April to May. It
flowers in June, but produces seed sparingly, relying
on its extensive root system for spread. Seeds can
remain viable in the soil for up to 22 years (Beck
2013). The key to managing this thistle is to stress
the plant, forcing it to use its stored root nutrients
(Beck 2013).
Biological control: The weevil Ceutorhyncus litura is currently being used in Colorado as a
biocontrol agent, and another biocontrol insect, Urophora cardui, has also been used (Beck
2013). Biological controls alone are not effective and must be used in conjunction with other
strategies such as cultural and chemical practices.
Mechanical control: Mowing decreases plant vigor and seed set. However, mowing may not be
viable given the plant's dispersal in riparian areas. Hand pulling is effective to control small
populations, but is not practical for large populations due to the deep and extensive network of
underground rhizomes. When seed heads are encountered they should be clipped well below the
apex, bagged, and disposed of in a dumpster. Mowing is effective only if conducted at one-
month intervals over several growing seasons, or used with chemical practices (Beck 2013).
Chemical control: Herbicides should be used only per label directions, and caution should be
taken since the weed occurs near water where many chemicals can harm aquatic life. Herbicides
should be applied by licensed commercial applicators. Research from Colorado State University
shows that picloram, aminopyralid, clopyralid, aminocyclopyrachlor + chlorsulfuron, dicamba,
and chlorsulfuron are effective in pastures, natural areas, and non-crop settings (Beck 2013). Re-
treatment for 1-3 years is common.
Cultural control: Increase competition with native perennial grasses and alfalfa. Keep moisture at
optimum levels to favor grass or alfalfa growth (Beck 2013).
Integrated management: Control efforts should target plants in high-quality areas first.
Management strategies should be adjusted to reflect weather conditions. For example, drought
stress reduces the effectiveness of most herbicides but increases the effectiveness of mechanical
controls. It takes at least two years of control to determine if a method is effective.
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Wetland Restoration Plan
Cheatgrass
Bromus tectorum is an exotic winter annual grass that is
one of the most widely distributed weeds in the western
U.S. Cheatgrass has been shown to significantly alter
the fire regime of ecosystems (D’Antonio and Vitousek
1992). It is an erect-stemmed, annual grass that grows
8-25 inches tall. The flowering part of the grass is
generally nodding with slender, straight awns. It
germinates in the fall or early spring and sets seed from
May to June. Cheatgrass flourishes in moderately to
highly disturbed upland sites such as roadways,
overgrazed areas, and waste sites. It initiates early
spring growth and aggressively uses deep soil resources.
Seeds are dispersed by animals and people who
transport seeds in fur, socks, boots, muddy tires, etc.
Because seeds remain viable for up to five years, control
measures that reduce seed are most effective.
Biological control: Intense grazing can reduce seed
production by 90%. Cattle find cheatgrass highly palatable in early spring before seed set occurs.
Once seed set occurs, plants drop in palatability and quality. Where infestations are large and
dense, prescribed spring grazing repeated for 3 to 5 years by livestock can be effective, and
indeed may be the only option in areas where it is difficult or impractical to implement other
prescriptions (Shoderbek 2015).
Mechanical control: Mechanical control efforts are not recommended unless they are followed
by an aggressive revegetation and chemical control program. When mechanical control is used, it
should be done in early spring before seed heads are fully developed (early to mid-May) and
repeated for at least 5 years. For small infestations, hand-pull weeds. For larger infestations,
mow before seed set, repeating every 2 to 3 weeks until flowering is complete (USFS 2014).
Chemical control: Rejuvra is a pre-emergence herbicide that works to stop cheatgrass while it’s
germinating by inhibiting normal root growth. If applying after germination, mix with a post-
emergence herbicide such as Plateau or Rimsulfuron (mid-August to mid-October), or Roundup
Pro Concentrate or Rimsulfuron + NIS (late-October through April) as per label instructions. It is
not recommended to allow cattle to graze immediately after application (Learn about Rejuvra
[date unknown]; D. Sebastian, e-mail message, October 29, 2021).
Cultural control: Due to the broad distribution of this plant, tilling and seeding operations are not
practical. In areas where revegetation efforts have not produced a healthy stand of perennial
grass cover, inter-seeding with native perennial grasses, following cheatgrass spot-control, can
be effective. Prescribed burns in areas with mixed shrub and grasses during late spring to early
summer have been used with some success, but burning is most effective when used in
combination with chemical methods and rigorous reseeding of native perennials (USFS 2014).
Integrated management: Lasting control of cheatgrass requires a combination of chemical and
mechanical control, reseeding with native perennials, and proper livestock management where
land is grazed. This method keeps plants under stress, reducing their ability to spread.
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Common Mullein
Common mullein (Verbascum thapsus) is a biennial forb that can easily be identified by its
yellow flowers grouped in a "corn cob" shaped flowering raceme. The leaves are light green and
densely wooly. Mature plants have a single, erect stem that can grow 6 to 8 feet in height. Seeds
germinate in the early spring, forming a rosette that continues to grow into late autumn and over
winter. A tall stem topped with the flowering raceme is produced the following spring. Common
mullein can be hard to control due its prolific seed production. The seeds can germinate after
lying dormant for several decades. Mullein is easily outcompeted in areas with a densely
vegetated ground cover but readily grows in disturbed sites, such as areas that have high human
activity or an abundance of bare ground. Mullein prefers dry coarse-textured soils, and is
common throughout Colorado in pastures, meadows, waste areas, and along river bottoms.
Biological control: The European curculionid (Gymnetron tetrum) feeds on the seeds and has
some success in reducing seed production, though there is little recent research on the subject
(Gross and Werner 1978).
Mechanical control: Mullein plants have shallow tap roots and are easily hand-pulled. They
should be pulled as soon as they are large enough to grasp but before they produce seeds.
Mullein stems can be cut or mowed to prevent flower and seed production, but stems must be cut
below the root crown or rosettes will re-bolt (CNAP 2000). We recommend planting native
perennials after mechanical control because mullein favors bare soil.
Chemical control: Herbicide application is most effective during the rosette stage. Due to the
wooly nature of the leaves, herbicides should be mixed with a surfactant to facilitate uptake.
Effective herbicides include metsulfuron at 0.6 oz. ai/acre, tebuthiuron at 4-6 lb. ai/acre (CNAP
2000).
Cultural control: Minimize disturbance and seed dispersal, eliminate seed production and
maintain healthy native communities. Mullein is often an early invader of burned areas.
Integrated management: Management efforts must include the elimination of seed production
and the depletion of the seed bank. Combine herbicide or mechanical removal of rosettes with
removal of seed heads from any plants that have bolted as well as reseeding bare areas with
native perennials.
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Wetland Restoration Plan
Dalmatian Toadflax
Linaria dalmatica is an exotic perennial forb that
easily invades natural ecosystems, thereby
displacing native vegetation. It has yellow flowers
with an orange lip. The leaves are heart-shaped and
clasp the stem. Dalmatian toadflax germinates from
mid-March to May, and flowers from May to June
and given sufficient moisture, can continue
flowering into the fall. By initiating early top growth
from underground roots (which can reach a depth of
6 feet or more), it effectively competes with native
plants for light, soil moisture, and other nutrients. It
spreads efficiently from seed as well as from root
buds that can travel underground up to 10 feet. In
wet years, these plants reproduce abundantly from
seed. However, since seedling root development is
slow, this represents a life stage vulnerable to
control. All toadflax species are difficult to control,
so it is recommended to integrate as many
management strategies as possible for successful
management (Beck 2014).
Biological control: Several biocontrol agents have been used to control toadflax but the success
of these agents has not been sufficient. A defoliating moth (Calophasia lunula), an ovary-feeding
beetle (Brachypterolus pulicarius), and two seed capsule-feeding weevils (Gymnaetron
antirrhini and G. netum) have been used in the U.S. and Canada. These flower- and seed-feeding
beetles should help decrease seed production. Mecinus janthinus, a stem-boring weevil, and a
root-boring moth, Eteobalea intermediella, were also released in Canada and the U.S. to control
all species of toadflax. These species help to control shoots and seed production as well as
decrease root vigor, but research is lacking (Beck 2014).
Mechanical control: Disturbance promotes the invasion of toadflax and it may be necessary for
plant establishment. Mowing combined with spraying was not found effective in a study from
Colorado (Beck 2014).
Chemical control: Tordon 22K at 2 pints/acre sprayed at the time of flowering or in the fall has
proven successful in Colorado. Spraying as well as planting native perennial grasses is more
effective than spraying alone (Beck 2014).
Cultural control: There is very little research supporting cultural controls being effective against
this weed in Colorado.
Integrated management: Successful management requires integrating as many control tactics as
possible. Control can be obtained by pulling or killing the plants with herbicide before seed
production begins. This process must be repeated every year for at least 10 years to completely
remove a stand. Competitive perennial grasses and forbs should be planted to utilize water and
nutrients that would otherwise be readily available to toadflax.
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Wetland Restoration Plan
Field Bindweed
Field bindweed (Convolvulus arvensis) is a
perennial forb identifiable by its leaves, which are
the shape of arrowheads, and its white to pink
funnel-shaped flowers. It favors areas with drought-
stress and poor irrigation coverage. Flowers appear
from June to September, and seeds mature within
two weeks after pollination during hot summer days.
Germination can occur in the fall or spring. Field
bindweed can be a serious threat to native plant
communities because of its high capacity for
regeneration. Its seeds can easily live for 50 years in
the soil, and its tremendous root system and
rhizomes have the potential to produce large
numbers of new shoots. It is highly competitive in
most areas. However, field bindweed cannot tolerate
shade, and it is unlikely that it would persist in later
stages of community succession (CNAP 2000).
Biological control: A small mite, Aceria malherbae,
has been found to be somewhat effective in
controlling bindweed in conjunction with other
management practices. The mites infest the new
growth of the plant by forming a leaf gall. This
reduces flowering and stunts stem growth. The mites will overwinter on the root buds and
emerge again in the spring. The mites should be released in a thick infestation that will not be
sprayed with chemicals or receive heavy watering (Field Bindweed Biocontrol [date unknown]).
Mechanical control: Mowing or hoeing may be an effective tool to manage bindweed and it may
help spread Aceria malherbae to new locations, though mowing may be hard because of the
plant’s low growth habit (Field Bindweed Biocontrol [date unknown]). Remove as many deep
horizontal rhizomes as possible. Apply repeated mechanical treatments when plants are young.
Chemical control: Pre-emergence herbicides are not recommended because of bindweed’s
extensive root system; systemic post-emergence products must be used. Foliar application of
glyphosate at 1.5 lb. ai/acre or picloram at 0.25-0.5 lb. ai/acre or 2-4 D at 1lb. ai/acre can be
effective. Repeated applications are recommended. Quinclorac is highly effective at controlling
bindweed. The chemical can be found in some commercial products. These herbicides are
labeled to only be used in lawns and cannot be legally or safely used in landscape beds or
vegetable gardens (Bindweed Control in Lawns [date unknown]).
Cultural control: Maintain a healthy cover of native perennial plants to discourage field
bindweed establishment.
Integrated management: Field bindweed requires active management once it is established
because of its potential to regenerate rapidly. Successful treatment of bindweed can result in
significant damage to desirable vegetation.
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Wetland Restoration Plan
Leafy Spurge
Euphorbia esula is an aggressive, long-lived perennial
weed that displaces native plants in many habitats
(Biesboer 1998). Leafy spurge produces a large number of
seeds and has extensive lateral root systems with which it
can reproduce vegetatively. These two reproductive
strategies allow this plant to rapidly form monocultures.
Large nutrient reserves in root systems allow this plant to
re-establish in treated areas; it also produces an
allelopathic compound that inhibits growth of other plants
(Butterfield et al. 1996). Spurge can grow in a wide variety
of habitats, but is best adapted to semi-arid settings. It
typically occurs in untilled rangelands and is most
abundant on coarse textured soils. Leafy spurge emerges
early in the spring (mid April to late May), flowering ends
in June to mid July. Photo from Whitson et al. (1996).
Biological control: The Division of Plant Industry’s
Biological Pest Control Section has released eight species
to control leafy spurge. The most effective biological
control agents are six species of root and foliage feeding
beetles in the genus Aphthona, and a stem and root boring beetle Obera erythrocephala
(Lajeunesee et al. 1999).
Mechanical control: Tillage is not practical in many areas, mowing can increase plant density
and may not be effective when combined with herbicide. Hand pulling is ineffective due to
extensive root systems. Burning is moderately effective when it is combined with herbicide
application after five weeks.
Chemical control: Herbicide applications can be successful but successive treatments are
required due to the extensive root systems of this plant. A combination of picloram and 2,4-D (1-
1.5 pints of picloram with 1-1.5 quarts of 2,4-D) has shown to provide best control when applied
in the spring when flowers emerge (Beck 1996). Picloram at 1 quart/acre for two to three
consecutive years is also effective, but costly. An annual combination of dicamba plus 2,4-D (4-
8 ounces with 0.5 to 1 quart per acre) also provided good control (Beck 1996). Glycoghosate is
most effective when applied sequentially at 1 quart/acre at one month intervals, coupled with fall
grass seeding (Beck 1996).
Cultural control: Long-term control requires the establishment of competing vegetation. Seed
mixtures should contain plants with early, mid and late growth as well as shallow, intermediate
and deep roots.
Integrated management: Leafy spurge is extremely difficult to control by chemical means and
almost impossible to control with cultural or mechanical means. Therefore a management
scheme that combines control methods over four to five years is recommended (Beck 1996).
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Wetland Restoration Plan
Musk Thistle
Carduus nutans is an exotic winter annual or
biennial that flowers from July to late September. It
has bright purple flowers (3 inches wide) that are
nodding (State Designated Noxious Weeds). The
leaves are dark green with light-colored, spiny and
deeply lobed margins (State Designated Noxious
Weeds). It generally invades areas that are
overgrazed or are experiencing poor perennial grass
cover; establishment is favored by high levels of
moisture and light. The average plant produces more
than 10,000 seeds that are readily dispersed by the
wind, thereby infesting large areas within two
growing seasons, and are viable for up to 10 years in
the soil (State Designated Noxious Weeds). Control
can be obtained by reducing seed set and depleting
the seed bank.
Biological control: The musk thistle rosette weevil,
or crown weevil, (Trichosirocalus horridus), is the
only biological control agent released by the
Colorado Department of Agriculture Insectary. The
weevil occurs in the developing root tissue of the
plant, stunting the growth and number of stems C.
nutans can produce. The plant stem and foliage will
start to yellow as the weevil damage accumulates
(Musk Thistle Biocontrol [date unknown]).
Mechanical control: Mowing with a weed whip or scythe can be a useful mechanical control
when plants are just beginning to flower to reduce seed set. Repeat treatments are necessary
because individual plants of C. nutans do not bloom at the same time. Grubbing or digging,
being sure to get the root, can be effective as well. Mechanical control should be combined with
biological methods.
Chemical control: Effective chemical control has been achieved in the past using picloram
(Tordon 22K), clopyralid (Transline, Stinger), clopyralid plus 2, 4-D (Curtail), chlorsulfuron
(telar), glyphosate (Roundup/Rodeo), dicamba (Banvel), and 2, 4-D. Applications should be
made in late spring/early summer and again in the fall.
Cultural control: We recommend inter-seeding disturbed sites to prevent the spread of this plant.
If competitive vegetation is not established, re-invasion is likely.
Integrated management: Prevent seed production. Most control methods have a detrimental
effect on other plants and may cause a disturbance that favors other exotic species. Dense musk
thistle stands along roadsides and in degraded areas can be treated by spot use of herbicides, and
in high quality areas by persistent pulling or cutting. Up to 10 years of control may be needed to
completely eliminate a stand.
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