Difference between revisions of "Plant lists"

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[[File:Toronto Botanical Garden_Jen.jpg|thumb|Wonderful plants varying in form, texture and colour, TBG ON]]
The vegetation is a big opportunity to maximize the co-benefits of biodiversity and amenity. Planting plans can be formalized or naturalized to suit the surrounding style. In addition to aesthetic qualities, plants have specific functions in several LID practices. These include promotion of [[infiltration]], treatment of pollutants<ref> Hunt, W. F., Lord, B., Loh, B., & Sia, A. (2015). Plant Selection for Bioretention Systems and Stormwater Treatment Practices. Singapore: Springer Singapore. https://doi.org/10.1007/978-981-287-245-6</ref> and stabilization of soil. When selecting plants for an LID practice, aim for species with high functionality, survivability, suitability and availability. Landscape professionals should use these lists as guides, taking into consideration the appropriate planting zone, the size of the planting area versus size of the plant at maturity, tolerances to drought or periodic inundation, maintenance requirements and adaptability.
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*To help you select appropriate plants for your site, we've developed tables to indicate the suitability for use in LID features.
*For resilient and robust planting, native species which can tolerate periods of drought and periodic inundation are recommended.
*Woody and evergreen plants should not be planted in any areas of the [[bioretention]] cell to be used as [[Winter|snow storage]].
*Dense shrubby plants should be avoided in locations where the accumulation of trash  is anticipated as a maintenance problem, or where their growth can hinder maintenance and inspection of [[inlets]] or [[Overflow|other structures]].
*[[Trees]] should not be planted directly over underdrains, and may be better sited at the perimeter of bioretention cells.
*While it is not always necessary to use an entirely native planting palette, invasive plants are inappropriate for LID practices. 


Plants have specific functions in relation to LID practices as well as aesthetic qualities. These include promotion of [[infiltration]], treatment of pollutants and stabilization of soil. The plant species that have been selected for each LID practice as described in the plant list table have been selected based on functionality, survivability, suitability and availability. The landscape professional should use this list as a guide, taking into consideration the appropriate planting zone, the size of the planting area versus size of the plant at maturity, tolerances to drought or periodic inundation, low maintenance requirements and adaptability. Invasive plants are inappropriate for LID practices.
==Plant Selection==
These pages contain a lot of images and may take a little longer to load.


==Plant Tables==
{{Clickable button|[[Trees: List|Select trees]]}}
{{Clickable button|[[Shrubs: List|Select shrubs]]}}
{{Clickable button|[[Perennials: List|Select perennials]]}}
{{Clickable button|[[Vines: List|Select climbing plants]]}}
{{Clickable button|[[Graminoids: List|Select tall grasses]]}}
{{Clickable button|[[Green roofs: Planting|Select plants for green roofs]]}}
{{Clickable button|[[Wetlands: Plants|Select plants for wetlands]]}}


<div class="toccolours mw-collapsible mw-collapsed">
==Plant Characteristics==
==Perennials==
===Soil moisture===
<div class="mw-collapsible-content">
{{:Forbs: List}}
</div></div>
 
<div class="toccolours mw-collapsible mw-collapsed">
 
==Grasses==
<div class="mw-collapsible-content">
{{:Graminoids: List}}
</div></div>
 
<div class="toccolours mw-collapsible mw-collapsed">
==Shrubs==
<div class="mw-collapsible-content">
{{:Shrubs: List}}
</div></div>
 
<div class="toccolours mw-collapsible mw-collapsed">
==Trees==
<div class="mw-collapsible-content">
{{:Trees: List}}
</div></div>
 
Each table describes species characteristics to help LID designers select appropriate vegetation. The definitions of these characteristics are:
 
===Soil Moisture===
Plant species are adapted to specific levels of moisture to achieve establishment and sustained growth. Soil moisture has been characterized by three categories: dry (1), moist (2) and wet (3). Some plants can tolerate a wide range of moisture regimes, whereas others perform optimally in a more narrow range of soil moisture conditions. Species ranked with a dash between two numbers can tolerate a range of conditions.
Plant species are adapted to specific levels of moisture to achieve establishment and sustained growth. Soil moisture has been characterized by three categories: dry (1), moist (2) and wet (3). Some plants can tolerate a wide range of moisture regimes, whereas others perform optimally in a more narrow range of soil moisture conditions. Species ranked with a dash between two numbers can tolerate a range of conditions.


===Partial Shade Tolerance===
===Shade tolerance===
Plant species react differently to varying levels of sunlight and shade.  Plant adaptations to these parameters are referred to in terms of degree of exposure. Most of the LID practices will be installed in newly developed areas, thereby providing exposure to full sun, meaning at least 6 full hours of direct sunlight for plantings. As trees develop over several years, or if an LID practice is installed in an area where there are existing trees or buildings providing partial shade, plants adapted to 3 to 6 hours of sunlight exposure should be used. Plants tolerant of full shade require less than 3 hours of direct sunlight each day. However, some shade-adapted species come into leaf early in the growing season in order to take advantage of full sunlight before tree leaves emerge and create shade.
Plant species react differently to varying levels of sunlight and shade.  Plant adaptations to these parameters are referred to in terms of degree of exposure. Most of the LID practices will be installed in newly developed areas, thereby providing exposure to full sun, meaning at least 6 full hours of direct sunlight for plantings. As trees develop over several years, or if an LID practice is installed in an area where there are existing trees or buildings providing partial shade, plants adapted to 3 to 6 hours of sunlight exposure should be used. Plants tolerant of full shade require less than 3 hours of direct sunlight each day. However, some shade-adapted species come into leaf early in the growing season in order to take advantage of full sunlight before tree leaves emerge and create shade.


Our tables indicate whether the species in question is tolerant of shade at all. For more information, consult the sources listed below.
Our tables indicate whether the species in question is tolerant of shade at all. For more information, consult the sources listed below.


===Drought Tolerance===  
===Drought tolerance===  
These categories represent broad generalisations regarding drought tolerance.


These categories represent broad generalizations regarding drought tolerance.
===Salt tolerance===
The low, medium and high categories indicate the tolerance of plant species to [[salt]] exposure and/or uptake. Plant species with low salt tolerance should not be used in any LID practice receiving runoff from salted roads and parking lots. Species with medium salt tolerance can be utilised in LID practices that will be receiving road runoff but should not be in the line of salt spray or be receiving the bulk of the runoff. Species with high salt tolerance should be planted in LID practices that receive road or parking lot runoff that routinely contains road salt.  Few plants are truly halophytic or “salt-loving”.  In most cases, elevated salt levels are temporary and precipitation quickly dilutes and removes salt from the soil profile. The plant lists below include recommended species for LID practices likely to receive road or parking lot runoff.
===Compaction and pollution tolerance ===
Development nearly always causes compaction of on-site soil, and bioretention facilities  in road-right-of-ways should be pollution tolerant.


===Salt Tolerance===  
===STEP stars===
The categories of Low, Medium and High are indicative of the tolerance of plant species to salt exposure and/or uptake. Plant species with low salt tolerance should not be used in any LID practice that receives runoff from salted roads and parking lots. Species with medium salt tolerance can be utilized in LID practices that will be receiving road runoff but should not be in the line of salt spray or be receiving the bulk of the runoff. Species with high salt tolerance should be planted in LID practices that receive road or parking lot runoff that routinely contains road salt.  Few plants are truly halophytic or “salt-loving”.  in most cases elevated salt levels are temporary and precipitation quickly dilutes and removes salt from the soil profile. The Master Plant List includes some species that are recommended for planting should be planted in LID practices that are likely to receive road or parking lot runoff.
These are species which have demonstrated good performance in projects designed, installed and monitored by the Sustainable Technologies Evaluation Program.


===Pollution and Compaction Tolerance===
{| class="wikitable"
 
|+ Advanced plant selection criteria<ref>Muerdter, C.P., C.K. Wong, and G.H. LeFevre. 2018. Emerging investigator series: the role of vegetation in bioretention for stormwater treatment in the built environment: pollutant removal, hydrologic function, and ancillary benefits. Environ. Sci. Water Res. Technol. 4(5): 592–612. doi: 10.1039/C7EW00511C.</ref>
WORDS HERE
|-
 
!Plant characteristic
===STEP Stars===
!Potential benefit to LID performance
 
|-
WORDS HERE
|Plant mass
|Higher biomass consumes more [[Nutrients|nutrients]] (decreases nutrient discharge from bioretention) and increases [[Evapotranspiration#Transpiration|transpiration]] rate.
|-
|Growth rate
|Higher growth rate consumes more nutrients, particularly in combination with root characteristics as below.
|-
|Root lipid content
|Higher root lipids have been associated with increased plant uptake of organic contaminants such as polyaromatic hydrocarbons (PAHs)
|-
|Root length
|Longer roots are associated with plants consuming more nutrients, although roots which reach the bottom to the media may contribute nutrient...
|-
|Root mass and thickness
|Larger overall root mass and many dense fine roots are associated with increased nutrient uptake by plants. Thicker roots help to preserve hydraulic conductivity of the media.
|-
|High-nutrient tolerance
|Plants adapted to high nutrient environments are likely to uptake nutrients at a higher rate.
|}


==See Also==
==See Also==
See [[Plant Standards]] for specifications, and [[Bioretention: Planting plans]] for design advice.
*[[Planting design]]
*[[Swales|Bioswales]]
*[[Swales|Bioswales]]
*[[Rain gardens]]
*[[Rain gardens]]
*[[Trees]]
*[[Materials]]
*[[Materials]]
*[[Bioretention]]
*[[Bioretention]]
*[[Green roofs]]
*[[Wetlands]]


==External resources==
==External resources==
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! Organization !! Coverage !! Types of Material  !! Website
! Organization !! Coverage !! Types of Material  !! Website
|-
|-
| Evergreen Native Plant Database || Canada / Ontario || Grasses, Ferns, Herbaceous, Shrubs, Trees, Vines  || http://nativeplants.evergreen.ca/  
| Watersheds Native Plant Database || Canada / Ontario || Grasses, Ferns, Shrubs, Trees, Vines  || https://watersheds.ca/plant-database/
|-
|-
| Online Plant Guide || USA || Grasses, Ferns, Herbaceous, Shrubs, Trees, Vines, Ornamental || http://onlineplantguide.com/Index.aspx
| Online Plant Guide || USA || Grasses, Ferns, Herbaceous, Shrubs, Trees, Vines, Ornamental || http://onlineplantguide.com/Index.aspx
Line 75: Line 86:
|-
|-
| United States Department of Agriculture || N. America || Grasses, Ferns, Herbaceous, Shrubs, Trees, Vines, Ornamental || https://plants.usda.gov/java/
| United States Department of Agriculture || N. America || Grasses, Ferns, Herbaceous, Shrubs, Trees, Vines, Ornamental || https://plants.usda.gov/java/
|-
| University of Connecticut || USA  || Shrubs, Trees, Ornamentals || http://www.hort.uconn.edu/plants
|}
|}


*Plant Selection for Bioretention Systems and Stormwater Treatment Practices<ref>Hunt, W. F., Lord, B., Loh, B., & Sia, A. (2015). Plant Selection for Bioretention Systems and Stormwater Treatment Practices. Singapore: Springer Singapore. https://doi.org/10.1007/978-981-287-245-6</ref>
*Leaf and fruit identification for trees and shrubs<ref>http://leafsnap.com/species/</ref>
 
----
----


[[Category: Green infrastructure]]
[[Category: Green infrastructure]]
[[Category: Landscaping]]
[[Category: Landscaping]]

Latest revision as of 15:25, 15 July 2020

Wonderful plants varying in form, texture and colour, TBG ON

The vegetation is a big opportunity to maximize the co-benefits of biodiversity and amenity. Planting plans can be formalized or naturalized to suit the surrounding style. In addition to aesthetic qualities, plants have specific functions in several LID practices. These include promotion of infiltration, treatment of pollutants[1] and stabilization of soil. When selecting plants for an LID practice, aim for species with high functionality, survivability, suitability and availability. Landscape professionals should use these lists as guides, taking into consideration the appropriate planting zone, the size of the planting area versus size of the plant at maturity, tolerances to drought or periodic inundation, maintenance requirements and adaptability.

  • To help you select appropriate plants for your site, we've developed tables to indicate the suitability for use in LID features.
  • For resilient and robust planting, native species which can tolerate periods of drought and periodic inundation are recommended.
  • Woody and evergreen plants should not be planted in any areas of the bioretention cell to be used as snow storage.
  • Dense shrubby plants should be avoided in locations where the accumulation of trash is anticipated as a maintenance problem, or where their growth can hinder maintenance and inspection of inlets or other structures.
  • Trees should not be planted directly over underdrains, and may be better sited at the perimeter of bioretention cells.
  • While it is not always necessary to use an entirely native planting palette, invasive plants are inappropriate for LID practices.

Plant Selection[edit]

These pages contain a lot of images and may take a little longer to load.

Select trees Select shrubs Select perennials Select climbing plants Select tall grasses Select plants for green roofs Select plants for wetlands

Plant Characteristics[edit]

Soil moisture[edit]

Plant species are adapted to specific levels of moisture to achieve establishment and sustained growth. Soil moisture has been characterized by three categories: dry (1), moist (2) and wet (3). Some plants can tolerate a wide range of moisture regimes, whereas others perform optimally in a more narrow range of soil moisture conditions. Species ranked with a dash between two numbers can tolerate a range of conditions.

Shade tolerance[edit]

Plant species react differently to varying levels of sunlight and shade. Plant adaptations to these parameters are referred to in terms of degree of exposure. Most of the LID practices will be installed in newly developed areas, thereby providing exposure to full sun, meaning at least 6 full hours of direct sunlight for plantings. As trees develop over several years, or if an LID practice is installed in an area where there are existing trees or buildings providing partial shade, plants adapted to 3 to 6 hours of sunlight exposure should be used. Plants tolerant of full shade require less than 3 hours of direct sunlight each day. However, some shade-adapted species come into leaf early in the growing season in order to take advantage of full sunlight before tree leaves emerge and create shade.

Our tables indicate whether the species in question is tolerant of shade at all. For more information, consult the sources listed below.

Drought tolerance[edit]

These categories represent broad generalisations regarding drought tolerance.

Salt tolerance[edit]

The low, medium and high categories indicate the tolerance of plant species to salt exposure and/or uptake. Plant species with low salt tolerance should not be used in any LID practice receiving runoff from salted roads and parking lots. Species with medium salt tolerance can be utilised in LID practices that will be receiving road runoff but should not be in the line of salt spray or be receiving the bulk of the runoff. Species with high salt tolerance should be planted in LID practices that receive road or parking lot runoff that routinely contains road salt. Few plants are truly halophytic or “salt-loving”. In most cases, elevated salt levels are temporary and precipitation quickly dilutes and removes salt from the soil profile. The plant lists below include recommended species for LID practices likely to receive road or parking lot runoff.

Compaction and pollution tolerance[edit]

Development nearly always causes compaction of on-site soil, and bioretention facilities in road-right-of-ways should be pollution tolerant.

STEP stars[edit]

These are species which have demonstrated good performance in projects designed, installed and monitored by the Sustainable Technologies Evaluation Program.

Advanced plant selection criteria[2]
Plant characteristic Potential benefit to LID performance
Plant mass Higher biomass consumes more nutrients (decreases nutrient discharge from bioretention) and increases transpiration rate.
Growth rate Higher growth rate consumes more nutrients, particularly in combination with root characteristics as below.
Root lipid content Higher root lipids have been associated with increased plant uptake of organic contaminants such as polyaromatic hydrocarbons (PAHs)
Root length Longer roots are associated with plants consuming more nutrients, although roots which reach the bottom to the media may contribute nutrient...
Root mass and thickness Larger overall root mass and many dense fine roots are associated with increased nutrient uptake by plants. Thicker roots help to preserve hydraulic conductivity of the media.
High-nutrient tolerance Plants adapted to high nutrient environments are likely to uptake nutrients at a higher rate.

See Also[edit]

External resources[edit]

Organization Coverage Types of Material Website
Watersheds Native Plant Database Canada / Ontario Grasses, Ferns, Shrubs, Trees, Vines https://watersheds.ca/plant-database/
Online Plant Guide USA Grasses, Ferns, Herbaceous, Shrubs, Trees, Vines, Ornamental http://onlineplantguide.com/Index.aspx
North American Native Plant Society N. America Grasses, Ferns, Herbaceous, Shrubs, Trees, Vines http://www.nanps.org/plant/plantlist.aspx
United States Department of Agriculture N. America Grasses, Ferns, Herbaceous, Shrubs, Trees, Vines, Ornamental https://plants.usda.gov/java/
  • Leaf and fruit identification for trees and shrubs[3]

  1. Hunt, W. F., Lord, B., Loh, B., & Sia, A. (2015). Plant Selection for Bioretention Systems and Stormwater Treatment Practices. Singapore: Springer Singapore. https://doi.org/10.1007/978-981-287-245-6
  2. Muerdter, C.P., C.K. Wong, and G.H. LeFevre. 2018. Emerging investigator series: the role of vegetation in bioretention for stormwater treatment in the built environment: pollutant removal, hydrologic function, and ancillary benefits. Environ. Sci. Water Res. Technol. 4(5): 592–612. doi: 10.1039/C7EW00511C.
  3. http://leafsnap.com/species/