Salt

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A graph showing increasing average levels of chloride found in Atherley Narrows, (a rural sampling location, between Lake Couchiching and Lake Simcoe), over the past few decades, due in part to increased use of rock salt in parking lots, roadways and commercial and residential properties. From 2005 - 2020 the amount of chloride increase per year has doubled when compared to 1971 - 1986 (1.26 mg/L per yr. vs. 0.63 mg/L per yr.) (LSRCA, 2021). It is estimated that by 2120 the average level of chloride within the the Lake Simcoe watershed will exceed the 120mg/L guideline set by CWQG. (LSRCA, 2018)[1]

Overview[edit]

Between 5 and 7 million tonnes of salt is applied every year in Canada for winter maintenance of roads and other paved surfaces, making it one of the most ubiquitous contaminants in urban environments. Canadians spend over $1 billion in winter maintenance costs to clear snow/ice on public and private roads, parking lots and sidewalks, this includes the use and application of greater than 5 million tonnes of rock salt for both deicing and anti-icing operations (Hossain et al., 2015)[2]. While the use of salt is essential to ensure public safety, there is a growing concern regarding the large quantities of salt (mainly chloride ions), being released to the environment.

NaCl- is the most common de-icer applied for winter maintenance, comprised of 40% sodium and 60% chloride. Sodium chloride rock salt is often treated with liquid MgCl2 and CaCl2 to reduce the effective temperature range of salts. Liquid brines comprised of NaCl- , MgCl2 and CaCl2 or a combination of these products are increasingly being used on roads for anti-icing to help reduce the amount of rock salt used and lower overall operations costs.

Impacts on the Environment, Human Health and Built Infrastructure[edit]

While salt is needed to keep roads safe in the winter, it is highly corrosive and toxic to freshwater wildlife at relatively low concentrations. Some of the impacts of salt on infrastructure, human health and the environment include the following:

Freshwater wildlife[edit]

Just as we depend on air with the right makeup of oxygen, freshwater species – like fish, frogs, mussels, salamanders and zooplankton – need water with the right balance of chloride to survive. Having adapted to low levels of chloride in their habitats, increased levels begin to disrupt their basic functions – such as regulating their water content (osmoregulation) and breathing. Studies have shown widespread effects of salt on ecosystems at all trophic levels from biofilms to fish species. Specific effects vary based on exposure concentrations, and may include reductions in fecundity, size, shape, growth and abundance (Hintz and Relyea, 2019)[3]

A study by researchers at Yale and Rensselaer Polytechnic Institute, in NY found the interactive effects of road salt on wood frog species' sex ratios and sexual size dimorphism. Over a series of experiments conducted, the authors of the paper in the Canadian Journal of Fisheries and Aquatic Sciences discovered that the number of females within the studied population of tadpoles decreased by ~10% when exposed to road salt. These findings suggest road salt may have a 'masculizing effect' on various amphibian species.[4]

Vegetation[edit]

Salt affects vegetation in various ways. Salt in soil water generally makes it more difficult for roots to take up water. This phenomenon mimics drought conditions for the plant and underlies the recommendation for salt tolerant plants in LID practices. If passing traffic sprays salty water onto plants it can reduce cold hardiness in buds and new twigs. These then become more susceptible to freezing, mortality or deformation. In high enough concentrations, sodium and chloride can also be directly toxic to plants. In some species the ions are absorbed by the plant and build up in the leaves causing them to die.

Soils[edit]

Dissolved sodium ions may replace calcium and magnesium ions in soil minerals, with negative effects on soil structure, hydraulic properties and fertility. Salt can also cause trace metals to be leached from the soil and into groundwater (e.g. Norrström and Bergstedt, 2001[5]; Norrström, 2005[6]). Excess salt (chloride) in soils can also result in decreased hydraulic conductivity, which can lead to increased occurrences of surface runoff, erosion and ultimately anaerobic soils, where plants would have a hard time establishing themselves (Shannon et al. 2020[7]).

Human Health[edit]

Salt has an unpleasant taste in drinking water at chloride concentrations above 250 mg/L. It also poses risks to people with hypertension or to those who have experienced congestive heart failure. Sodium from winter salts can also be dangerous for people on sodium restricted diets. These aesthetic and human health impacts of salt, combined with its high mobility in soils, has led to recommendations to limit implementation of infiltration-based LID in source water protection areas. This is of particular relevance for communities that utilize groundwater as their primary source of drinking water.

Terrestrial Wildlife[edit]

Ingestion of road salts has been associated with mammalian and avian behavioral and toxicological effects. Indirect effects of plant cover reductions or shifts in plant communicates can also negatively impact wildlife habitat (Fay and Shi, 2012)[8]. Deer, moose and other mammals attracted by salt on highways can increase the risk of vehicle collisions. Furthermore, various bird species can be be sensitive to even small amount of rock salt ingestion. These birds may be attracted to roads dude to salt deficient diets and foraging for "grit" (which aids in the birds digestion by grinding up hard to breakdown items). A 2005 study conducted by Bollinger, et al.[9] discovered that salt grain amounts similar in size foraged as grit by birds could contain lethal amounts of sodium for these birds. Ingestion of even a small number of road salt granules by some bird species (songbirds, etc.) could be a lethal dose as a result of sodium (Na) toxicity.

Built Infrastructure[edit]

Chloride based deicers are highly corrosive and can cause significant damage to vehicles, steel bridges, railings and other metal infrastructure. They can also cause damage to concrete structures by accelerating corrosion of re-bar within the concrete, which poses a problem for bridges, parking lots above underground garages or other contexts where the concrete contains metals. The salts may also react with the cement paste causing deterioration of the cement matrix in poured and pre-cast concrete pavers. Magnesium chloride (MgCl2) is particularly reactive in this regard, resulting in a decrease in concrete compressive strength (e.g. Shi 2009[10], Shi et al, 2009)[11].

Guidelines[edit]

Temporal changes in 5-year median chloride concentration (1966-2020). All stations had higher median chloride concentrations in 2016-2020 compared to the last time 5-year median concentrations were culminated into a report (2011-2015) and the difference in concentration between time periods appeared to be greater for stations with higher chloride concentrations. The reasons behind this pattern are unknown and warrant further investigation, but median concentrations are above the chronic level of 120 mg/L in all of the more urbanized watersheds, south towards Lake Ontario (TRCA, 2021).[12]
Average chloride concentration between 2016 - 2020 from collected grab samples. Most stations in the Southeastern part of TRCA's watershed within the Etobicoke, Mimico Creeks and the Humber River had much higher than the CWQG acute level of chloride (640mg/L), some at more than ~3 times this concentration (TRCA, 2021).[12].

Code of Practice[edit]

A comprehensive scientific assessment by Environment Canada and Health Canada determined that in sufficient concentrations, road salts containing inorganic chloride salts pose a risk to plants, animals and the aquatic environment (Environment Canada and Health Canada, 2001)[13] and are toxic substances as defined by the Canadian Environmental Protection Act, 1999 (CEPA 1999).[14]).

Following the designation of chloride as a toxic substance, the Government of Canada established a Code of Practice for the Environmental Management of Road Salts under CEPA to help municipalities and other road authorities to better manage road salt use and reduce the adverse impacts of chloride, which maintaining road safety (Environment Canada, 2004)[15].

The Code recommended, on a voluntary basis, that road authorities and municipalities applying more than 500 tonnes of road salt per develop salt management plans and implement best management practices for salt application, salt storage and snow disposal as described in the Transportation Association of Canada’s (TAC) Synthesis of Salt Management Best Practices (TAC, 2013)[16]. The Code does not address the use of road salt on parking lots and private property or its use as a dust suppressant but a Best Practice document specifically for these areas was developed by TAC in 2013.

Canadian Water Quality Guidelines for the Protection of Aquatic Life[edit]

The Canadian Water Quality Guidelines for the Protection of Aquatic Life[17] document from the Canadian Council of Ministers of the Environment (CCME) is another valuable paper that discusses the direct toxic effects of chloride, based on studies using NaCl and CaCl2 salts. The guideline can be used as a screening and management tool to ensure that chloride does not lead to the degradation of the aquatic environment. Further guidance on the application of these guidelines is provided in the scientific criteria document (CCME 2011), which can be found here - Scientific Criteria Document - Cl Ion. Both documents developed chloride toxicity thresholds for protection of aquatic in 2011 based on a comprehensive scientific review.

  • Chronic toxicity (long duration exposure): 120 mg/L
  • Acute toxicity (short duration exposure): 640 mg/L

Canadian Drinking Water Guidelines[edit]

The Canadian Drinking Water Guidelines (CDMG) are published by Health Canada. Health Canada updates its summary table for known irritants/pollutants and publishes it online every spring on their website here: (Health Canada's, Drinking Water Quality Table) (Health Canada, 2020)[18]. Below are the drinking water guidelines for both Chloride and Sodium found within rock salt:

  • An aesthetic objective for Chloride of 250 mg/L was developed for drinking water supplies based on taste and potential for corrosion in the distribution system.
  • Sodium also has an aesthetic objective of 200 mg/L based on taste, as well as a guideline of 20 mg/L for people on sodium restricted diets

Observed Chloride Levels in Streams Concentrations[edit]

Monitoring data show that our freshwater resources are become increasingly salinized, particularly in urban areas. As the graphic shows, several urban streams in the GTA have average chloride concentrations exceeding the chronic toxicity threshold, and at some monitoring stations, even the acute toxicity threshold is exceeded. This is not just a winter problem; it can take months for water to move through the soils and into the rivers, resulting in high concentrations even in the spring and summer during sensitive life stages for many aquatic species.

In 2022, on-line sensors were installed to measure chloride concentrations at the mouth of several GTA watersheds. The monitoring results included: (Wallace, et al. 2022.)[19]

  • Highland Creek: (Peak concentration of 8,400 mg/L) - 70 times the CWQG limit for chronic effects & 13 times the CWQG limit for acute effects of aquatic organisms.
  • Duffins Creek: (Peak concentration of ~3,000 mg/L) - 25 times the CWQG limit for chronic effects & ~5 times the CWQG limit for acute effects of aquatic organisms.

These high concentrations pose a considerable threat to fish, aquatic organisms, and ecosystem health overall - especially considering the frequency and duration of these values in major watercourses in urbanized areas of the province. The findings highlight the need for increased water monitoring efforts and requirements for new sensor technology to capture an accurate representation of the current state of our rivers and streams.

In previous years, chloride concentrations greater than sea level concentrations (19,000 mg/L) have been observed in tributaries of the Credit River.

Salt & LID[edit]

Example of a bypass in use to limit runoff from entering into a bioretention cell BMP. (Photo Source: TRCA, 2021)
The above graph shows research conducted by the STEP group comparing chloride level discharges between asphalt, and two commonly used LID practices (Permeable pavement and Bioretention). The results show that asphalt releases salt in concentrated bursts during winter whereas the LIDs release it more gradually over the entire year.

Since salt has deleterious effects on many plant species, there is often concern that plants in LID receiving salt laden road runoff will not fare well over time. Several design features are meant to address these risks, including:

In drinking water protection areas, bypasses may be used to limit exposure to road salts during winter months where aquifers are vulnerable and ensures that any heavily-laden stormwater will "bypass" the practice and flow to the downstream street inlet to the Municipality's storm sewer system.

LID typically delays the release of salt to receiving waters through temporary storage of elevated chloride levels in soils and then slowly releases it over time. This can help to reduce peak concentrations in discharges and push discharges into the spring when streams have greater dilution capacity. Runoff infiltration in LID practices also helps reduce salt loading to streams that can harm riparian, aquatic and semi-aquatic fauna and flora species.

Permeable pavements can improve drainage and prevent melt water from ponding and refreezing. Some permeable pavements also have higher friction coefficients that may reduce the amount of salt needed to create slip-free surfaces.

Salt Reduction Best Practices[edit]

Since salt is not removed by traditional best practices, reducing application rates to only what is needed to achieve pavement safety requirements is the best means of managing impacts of salt on the environment and infrastructure. Pavement friction testing has shown that salting beyond the required amount does not translate into improved safety: LSRCA's Technical Bulletin: Alternatives to Salt.[20]

A review of salt management best practices for parking lots, private drives and walkways is provided by STEP (2022)[21]. The Transportation Association of Canada's (TAC), Synthesis of Salt Management Best Practices[22] and Clear Roads research[23]and provides best practice resources more relevant to municipalities and road authorities. The following sections outline what property owners/managers and winter maintenance professionals can do to avoid excess salting.

Property Owners and Managers[edit]

Property owners and managers play a critical role in creating safe winter conditions and managing the environmental impacts of winter salt on their sites. Some key activities property managers and owners can do to limit salt use without compromising safety include:

Site Assessment and Planning[edit]

This activity is often done with contractors to identify appropriate snow storage areas, vehicle impact hazards, problem areas such as grading that directs melt water or precipitation to walkways, roof downspouts directed to paved areas, or infrastructure that could be damaged by snowplows. A winter maintenance policy stipulating the expected weather-based level of service, areas requiring winter maintenance and other guiding elements should also be developed as part of a winter risk management strategy. Certification of the property(ies) through the Smart about Salt Council can help property managers through the process of developing a plan and policy, while also demonstrating how the organization has endeavored to provide a reasonable level of care in the event of lawsuits.

On-Site Equipment[edit]

Salt storage and spreading equipment, such as salt boxes, liquid storage containers, and walkway spreading devices can be used by building management staff for periodic or spot treatments, which may reduce requests for contractors to return to the site to apply more salt. On-site mobile or in-pavement temperature and salt residue sensors, along with weather forecasting tools are also useful to inform salting decisions and provide building managers with tools to verify that the salting approaches applied to the site and discussed with contractors as part of the winter maintenance plan are appropriately tailored to site conditions.

Summary of Salt Reduction Measures and their estimated impact on salt use and contract costs from STEP's Procurement Guidance for Parking Lot Snow and Ice Management[24]

Record Keeping[edit]

Responsibilities for tracking winter conditions and maintenance activities should be shared by contractors and property management staff. On-site cameras can be particularly useful in this regard, particularly if the feeds' from these cameras are also shared remotely with contractors. Tracking equipment can help resolve potential conflicts between property management and contractors, contribute to learning through trial and error, ensure the winter maintenance plan is being followed and provide due diligence evidence in the event of slip and fall lawsuits. Liability for "slip and fall" claims associated with winter maintenance are outlined under "Bill 118 - Ontario’s Occupiers’ Liability Act". The Act was recently amended in January of 2021 and effectively disallows "any action for personal injury damages caused by snow or ice conditions against an occupier or independent contractor employed to remove snow or ice from the premises when the injury occurred unless a written notice of the claim is personally served on or sent by registered mail to such the occupier or independent contractor within 60 days" - Robert Kennaley, 2021[25] (some exceptions apply if the injury results in death, along with other more extreme cases). These recent changes will result in a reduction in associated claims and insurance payouts, thus leading to likely lower insurance premiums for contractors that historically have been high since the 1990s (Kennaley, 2021)[25].

Responsible Procurement[edit]

It is important that winter maintenance contracts be structured not only to ensure that salting and plowing activities promote safe conditions throughout the winter, but also to ensure that contracts are oriented towards minimizing the harmful effects of salt on freshwater ecosystems, drinking water, soils, vegetation and wildlife. Property owners, businesses and contractors have control over how much salt is applied through their snow and ice management contracts, and the diligence with which they manage and oversee these contracts. Some clauses and conditions that can be included in contracts to promote responsible use of winter salts include:

  • Requirements that snow and ice professionals be Smart about Salt certified;
  • Specification that various best management practices be used;
  • Clearly articulated expectations for level of service and salt application rates based on weather and site conditions;
  • Requirements for record keeping on salt use, time of applications and location;
  • Avoiding excessive use of hold harmless clauses that place undue legal liability burdens on contractors;
  • Structuring contract pricing structure based on number of events or season to avoid incentivizing salt use.

Examples of the types of best management practices that may be considered when preparing contracts are also provided in the STEP's Procurement Guidance for Parking Lot Snow and Ice Management report (STEP, 2019)[24], along with estimates of the impact on salt use, and the potential influence these may have on contract costs.

Minimizing the Area requiring Winter Maintenance[edit]

Properties with large parking lots often present owners with opportunities to close portions of parking lots and entranceways to public and employee use during the winter, either on a seasonal basis or during certain low use periods. Appropriate signage may need to be installed to inform staff and visitors that these areas are not to be used. This measure can generate significant savings through reduced material use and labour, while also reducing the potential area where snow and ice may contribute to safety and liability concerns.

Improved Parking Lot and Walkway Design[edit]

In new developments or when pavements are repaired or upgraded there are often opportunities to improve drainage, grading or pavement features to reduce the amount of salt needed during winter maintenance. Design changes may include, but is not limited to grading to keep meltwater away from trafficked areas, directing downspouts away from paved areas, installing windbreaks, avoiding flat grades that will eventually form depressions where water can puddle, creating designated snow storage areas that drain away from pavements and installing covers, heated pavements or pavement overlays that can be maintained with less salt (LSRCA, 2018)[26]. See below for more details.

Good Ontario resources on winter maintenance strategies for private businesses and property owners/managers include:


Winter Maintenance Professionals[edit]

Selected best management practices for winter maintenance professionals include the following (Van Seters, 2022)[21]

Best Practices for Winter Maintenance Professionals

Best Practice
General Description
Key Benefits
Contract pricing by season or event

(contractor and property owner/manager)

Snow and Ice professionals are paid a fixed priced per season or event. Reduces salt use by not incentivizing the use of salt through the pricing structure in contracts.
Site condition assessments and plans

(contractor and property owner/manager)

Site assessments and plans identify and document site conditions, problem areas to be rectified, service areas and levels, snow storage areas, and expectations. Improves operational efficiencies; supports due diligence defense; prevents potential client contractor conflicts; reduces the need for repeat salt applications on problem areas.
Flexible level of service requirements

(depending on conditions)

Since salt needs time to work, there is invariably a delay between when it is applied and when the specified bare pavement service level is met. This delay can be lengthened under circumstances when bare pavement is needed only during daytime business hours and the snowstorm ends several hours before the day starts. If applicable, flexible LOS requirements should be described in the site winter maintenance plan. Significantly reduces salt use because research has shown that the quantity of de-icer applied is strongly influenced by the bare pavement level of service target.
Materials Rock salt pretreated with liquid MgCl2 or CaCl2 lowers the effective temperature range of salt and reduces losses to wind and scatter. Low chloride alternatives can also significantly reduce the harmful effects of chloride-based salts. Reduces salt release to the environment and lowers corrosion effects on infrastructure. May also lead to improved level of service. For more information see STEP's Technical Brief: Alternatives to Salt (STEP, 2020)[27]. Abrasives such as sand do not melt snow and ice but may be appropriate in some circumstances and LSRCA, 2018[1].
Salt Specifications In Ontario, NaCl rock salts and brines used for snow and ice control should meet Ontario Provincial Standard Specifications (OPSS 2502, OPSS (Update) 2502) for moisture content, texture, and chemistry to ensure optimal performance. Rock salt texture and moisture helps regulate dilution rates, bounce, blow off and other factors that can negatively influence overall effectiveness.
Direct Liquid Application Involves applying brine before, during or after snow events to prevent ice formation on pavement and walkways. Anti-icing is the application of a brine or treated rock salt before snow events. Less salt is required to prevent ice -pavement bonding than to break the bond after it has formed. Salt savings of 39 to 46% are common. Can improve overall level of service and support due diligence defense.
Pre-Wetting Applying a concentrated liquid anti-icing rock salt at the spinner or chute increases moisture content, which in turn promotes quicker activation and better adherence of salt to pavements. Reduces salt use by approximately 20%. Similar benefits may be accomplished by pre-treating salt stockpiles with liquid or using proprietary pre-treated salt products.
Ground Speed Controllers Salt spreaders are equipped with controllers that automatically dispense salt based on truck speed. Research shows salt reductions up to 49% compared to manually controlled spreaders. Particularly relevant for parking lots where salt trucks are frequently required to vary speeds and stop/start.
Vehicle Tracking Equipment Use of Global Positioning System (GPS) and Advanced Vehicle Location (AVL) technologies that track the location of vehicles. Often implemented with controllers to provide operational data along with location data. When combine with operational data collection systems, GPS and AVL can improve operational efficiencies and increase operator accountability. The data are extremely helpful in supporting due diligence defense.
Decision Support Tools

(basic)

May include use of RWIS, pavement temperature and residual salt monitoring, on-site cameras and decision support software/systems. Example RWIS: Wood Weather Information System Helps optimize event-based winter maintenance strategy (timing, material selection, etc.); supports due diligence defense.
Equipment Calibration

(once a year and after repair)

Salt spreading equipment (solid and liquid) is calibrated to ensure it is functioning and applying salt at the calibrated rates. Both vehicle spreaders and walk behind drop spreaders should be calibrated. Ensures accurate and efficient delivery of material to pavements and walkways; avoids use of malfunctioning equipment; supports due diligence defense.
Plowing before Salting Plow at snow depth accumulations > 2 to 3 cm. Spreading salt on top of snow dilutes its effectiveness thereby requiring more salt to achieve desired level of service. Avoids dilution of salt and improves effectiveness, which significantly reduces salt use; more frequent plowing can support due diligence defense.
Segmented or Live Edge Snowplow Blades Segmented or Live Edge snowplow blades remove more snow than traditional blades by conforming better to the surface contours of the pavement. Reduces salt use because the salt applied is not diluted by residual snow on the surface; may provide higher level of service while also offering some support to due diligence defense.
Setting Application Rates

based on conditions

Establishing target liquid and solid de-icing material rates for a range of conditions based on temperature, residual salt on pavements, snowfall depth and duration and other key parameters. Rates suited to different conditions are ranges to allow for some decision-making flexibility Adjusting salt application rates according to conditions helps ensure that only the amount needed to promote safe conditions is used. Documentation supporting the selection of rates can help support due diligence defense.
Record Keeping Records and logs should be kept of equipment calibration and maintenance, weather, salt use by load, maintenance schedules, site conditions, staff training, site contracts, trouble spots and other parameters relevant to winter maintenance operations. See also site condition assessments and planning section above. Documentation supports due diligence defense and provides critical information for assessing overall performance and identifying where improvements may be needed. Often leads to significant salt reduction.
Material Storage and Handling De-icing materials should be covered and isolated from other site drainage. Spilled salt in handling areas should be collected and returned to the storage facility. Storage and handling areas should be impervious to prevent contamination of soils and groundwater. Vehicle wash water should be properly managed. Avoids unnecessary release of salt into the environment; reduces costs associated with material loss.
Snow Storage Snow should be stored in low sections of site to prevent melt water and re-freeze on pavements. Snow transported off site should go to proper snow disposal facility. Avoids release of salt into the environment; Reduces salt by eliminating re-freeze conditions that can cause repeat applications; supports due diligence defense.
Training Training of all winter maintenance staff through Smart about Salt Council and/or other equivalent certification programs. Training is widely recognized as a critical component to responsible use of salt; supports due diligence defense.

For more information on the practices and research supporting the suggested benefits, see STEP, 2022[21] and TAC, 2013, and associated reference materials.

Site Design Strategies for Salt Reduction[edit]

In 2017, LSRCA and its partner agencies developed the Parking Lot Design Guidelines[28] that can be used by designers, regulatory agencies, property owners, contractors, and others to implement design elements within parking lots and related infrastructure that help limit the need for salt. The web page for the initiative includes the full guideline report, a fact sheet and a municipal policy template to facilitate incorporation of guidelines into municipal policy. The report identified four key design strategies.

Effective Grading[edit]

  • Proper grading can minimize the freezing of wet pavement surfaces and prevent melt water from ponding and re-freezing, reducing the need for re-application of salt.
  • Areas for vehicular and pedestrian traffic should have well compacted subgrades with surface grades between 2 - 4 % to reduce the chances of depressions forming. Even shallow depressions will pond water and ice over in the winter, requiring frequent salting to avoid ice build-up.
  • Subbase should be well compacted for the same reason.
  • In winter months salt should be applied efficiently along the top of slopes to allow melting snow to carry the salt solution down-gradient.
  • Effective grading can also direct melt water towards strategically placed stormwater collection infrastructure (i.e. catch basins, vegetated swales, bioretention features, landscaped areas), preventing salt application in heavy traffic areas that are also pathways for runoff.
  • The key to effective stormwater collection during winter is to ensure that melt water from high traffic areas or snow piles does not have to travel great distances to a collection point (LSRCA, 2017)[28].

Snow Pile Location[edit]

Not quite well graded enough; the puddle in the foreground will refreeze overnight.
  • Snow piles should be strategically located to minimize the risk of melt water draining across high traffic areas and refreezing.
  • Storage locations for snow piles should be around the outer edges of parking lots and downgradient from high traffic areas, in sunny areas where possible to accelerate melting.
  • Consider grading the storage location to distribute the melt-water as sheet flow over a grass filter strip into an adjacent BMP, such as a bioretention cell or infiltration trench. In some cases, with careful vegetation selection and adequate drainage, the BMP itself can serve as a snow storage location. Designing specific drainage collection features for snow piles can ensure that melt water is quickly collected in the vicinity of the pile to reduce the opportunity for refreezing.
  • Snow storage locations should be included in the winter maintenance plan and clearly marked for seasonal maintenance staff (LSRCA, 2017)[28].

Sidewalk Design and Pedestrian Flow[edit]

  • The design process should consider that pedestrians typically follow the path of shortest distance and do not necessarily use designed walkways. Walkways from adjacent residential areas and transit stops should be prioritized, and unnecessary walkways should be avoided.
  • Sidewalks that receive infrequent use could be closed for the winter season.
  • Maintained sidewalks should be ≥ 1.5 m wide to accommodate plowing and minimize the salting required.
  • Using textured pavers or overlays can improve grip for pedestrians, reducing the salt required.
  • In busy areas around building entrances, covered walkways and heated mats also reduce salt requirements (LSRCA, 2017)[28].

Landscaping Features[edit]

Trees[edit]

  • Landscaping features (i.e. vegetated swales or landscaped islands) can lead to a reduced requirement of salt application by reducing the amount of paved surface.
  • Specifying deciduous trees along walkways and near snow piles will maximize winter sunlight penetration. This will naturally enhance the melting of frozen surfaces, limiting the need for winter maintenance.
  • Coniferous trees can be used to create treed "wind breaks" along the site perimeter to avoid snow blowing onto pavement.(LSRCA, 2017)[28].

Other vegetation[edit]

Picture showing an empty parking lot after a winter storm. An example of an area that could be closed off to users reducing the need for salting or other maintenance practices (shoveling, plowing services, etc.)

Vegetation varies in its reaction to soils with high salinity:

  • Salt in soil water generally makes it more difficult for roots to take up water. This phenomenon mimics drought conditions for the plant.
  • If passing traffic sprays salty water onto plants it can reduce cold hardiness in buds and new twigs. These then become more susceptible to freezing, mortality or deformation.
  • In high enough concentrations, sodium and chloride can also be directly toxic to plants. In some species the ions are absorbed by the plant and build up in the leaves causing them to die.

Generally, the vegetation growing closest to the source will be most strongly affected by salt. Plants actively growing in late winter (when salt levels are highest) are also more significantly affected. Therefore, warm season grasses offer an advantage over cool season grasses, because they emerge later in the spring when excess salt has been flushed away. Resilient turf grasses are particularly useful in the design of vegetated filter strips, dry ponds and enhanced grass swales. The Ministry of Transportation have standardized a number of grass mixes[29]. The 'Salt Tolerant Mix' is of particular value for low impact development applications alongside asphalt roadways and paved walkways.

Canada #1 Ground Cover (salt tolerant mix)
Common name Scientific name Proportion
Tall Fescue Festuca arundinacea 25 %
Fults Alkali Grass Puccinellia distans 20 %
Creeping Red Fescue Festuca rubra 25 %
Perennial ryegrass Lolium perrenne 20 %
Hard Fescue Festuca trachyphylla 10 %

For other species of trees and shrubs, see the Plant lists page for salt tolerant plants suitable for LID.

Example of three brine holding tanks that can reuse meltwater from salt induced snowmelt to be reused on a pavement surface i na high traffic area. These systems are generally built with corrosion-free materials to maximize the product's lifetime. Photo Source: Camion[30]

Other Design Features[edit]

Other options that can be considered to reduce the amount of salt that needs to be applied in a parking lot include:

  • Seasonally closing parking areas: many parking lots have areas that are infrequently used outside of the holiday shopping period. These areas can be closed and not maintained through much of the winter season, reducing both the effort and amount of salt required.
  • Shaded Canopies: With roof canopies over major pedestrian walkways and entrances from parking lots to building enclosures, little to no snow or ice will fall in these high-traffic areas, resulting in reduced salt application. Consideration should be taken for the runoff generated from the canopy stormwater or snowmelt when weather begins to warm to limit the potential for of ponding/refreezing on the walkway.
  • Conductive Pavement on Walkways/Entrances: Conductive pavements consist of electrically and thermally conductive materials mixed with the dielectric aggregates typically found in standard asphalt and concrete pavements. Once connected to a power or heat source, these pavements conduct electricity and emit heat to pavement surfaces, melting ice and snow with constant and uniform heat.
  • Brine holding tanks: Collection of first flush (high chloride concentration) melt water runoff from a salt induced snowmelt (as opposed to rain and temperature induced snowmelt) has the potential to be beneficial if captured and reused as an anti-icing or pre wetting solution. In order to collect the first flush runoff, an electronically actuated valve controlled by an electrical conductivity sensor would be installed at the desired conveyance point to divert and collect the high chloride concentration runoff into a brine holding tank. The brine holding tank would be placed below ground and a pump could be connected to pump the brine solution into an anti-icing tank or directly used to pre-wet rock salt. [31]

Case Studies & External Links[edit]

Case Studies[edit]

A series of STEP case studies highlighting the effectiveness of different salt management practices is currently being developed. A brief synopsis of some of these case studies is provided in Appendix B of Van Seters, 2022. Full case study documents will be posted here when available.

  • The 2021-2022 Road Salt Program at Ottawa Riverkeeper[32]
    • This ongoing study is being conducted to evaluate the feasibility and environmental benefits (specifically, the reduction of chloride (Cl) entering the environment) of using direct liquid application (i.e., NaCl brine) on Ryerson campus for both anti-icing and de-icing. Updated reports and findings will be posted here once published
De-icer agent applied to a roadway before a precipitation rent (Source: STEP, 2019)[33]
  • Using Liquids to Reduce Winter salt Use on Commercial Parking Lots[34]
    • This ongoing study is being conducted by Peel Regio and LSRCA staff, along with contractor International Landscaping Inc. to evaluate the feasibility and environmental benefits (specifically, the reduction of chloride (Cl) entering the environment) of using liquid anti-icing with NaCl brine (with and without beet juice additive) on commercial parking lots. Updated reports and findings will be posted here once published
  • Closing Areas to Reduce Salt Use and Winter Maintenance Costs[35]
    • Ongoing study by the Region of Waterloo to explore the feasibility and interest in reducing salt use and maintenance costs by establishing outreach campaigns and support programs that encourage property owners and managers (of ICI properties) to close under-used areas of their properties during the winter, which can be a very successful means to reduce salt use, and provide significant savings on winter maintenance costs.
  • Salt Application Best Practices document for Winter Maintenance Contracts[36]
    • Businesses can help reduce over-salting by ensuring that rock salt during the winter months is applied responsibly on parking lots and walkways. An easy way to do this is by ensuring that your snow and ice maintenance contract includes provisions requesting that industry best practices be employed and that associated operators are adequately trained. Some BMP for procurement for rock salt application services include:
      • Effective Pricing of Services
      • Accurate Salt Delivery
      • Reducing Liability Risk
      • Efficient Application
      • Consideration of Chloride Alternatives
      • Well Informed Decision Making Processes
      • Using Trained Professionals through the Ontario Smart about Salt Program
  • LSRCA's Technical Bulletin: Alternatives to Salt.[20]
    • This technical bulletin by LSRCA discusses the issue of high levels of salt application, and how contractors, property owners and municipalities can save time and money by looking at the emerging research which shows how salt use can also be optimized in parking lots. This research was done by using a friction tester, with a goal of quantifying the effectiveness of various practices and salt application rates.

External Links[edit]

Smart About Salt training program teaches winter contracting company staff and facility management staff how to appropriately apply rock salt and still being mindful about its environmental impact, all while reducing reducing liability and maintenance costs. To learn more, click the picture above.[38]
  • Smart about Salt[39]
    • The website of the Smart About Salt Council (SASC) that offers training, recommendations, research and up to date news articles about the importance of proper management and use of rock salt on Ontario roadways, parking lots, private and residential properties. Training is offered in both English and French.
  • Salt Application Verified Equipment (SAVE) Program: Managing Risk While Saving Money[40]
    • The Salt Application Verified Equipment (SAVE) Program was developed to make the process of applying salt less subjective and encourage contractors providing snow and ice management services for parking lots and sidewalks to apply salt more efficiently. Through the program, salt spreading equipment is calibrated according to a standard test procedure, and contractors undertake in-field training to ensure familiarity with how to operate their equipment in a manner that achieves pre-determined target salt application rates. Equipment operators obtain annually renewable license and plate stickers to confirm that their equipment has been verified. The list of contractors with calibrated equipment is made available on-line for facility managers, property owners and property management companies to use in the procurement of snow and ice maintenance contracts for their properties. To learn more about the program click Here. And for further updates to the program's verification process visit SASC's page here.
  • Good Practices for Winter Maintenance in Salt Vulnerable Areas. [41].
    • This guidance is a living document to help address the impacts of road salt, within specific vulnerable areas, and will be reviewed every two years to remain current with technological and legislative changes. There are several types of ‘salt vulnerable areas’, with various environment and human health goals including drinking water quality, wetland health, and fisheries that are identified within the document. This guidance currently prioritizes certain areas where municipal drinking water sources are known to be impacted by road salt, know as, ‘Issue Contributing Areas’ (ICAs) delineated under the Clean Water Act (2006).
  • Winter Parking Lot and Sidewalk Maintenance Manual[42]
    • The purpose of this manual By the Minnesota Pollution Control Agency (MPCA) is to deliver practical advice to those managing parking lots and sidewalks and help make proactive, cost-effective, environmentally conscious choices in winter parking lot and sidewalk management in the State of Minnesota. This knowledge will provide the opportunity to become a leader in the industry by operating more efficiently and reducing environmental impacts. The manual is based on the Minnesota Snow and Ice Control Field Handbook for Snowplow Operators, produced by the Minnesota Local Technical Assistance Program Center, and on the training materials for the MPCA's Winter Maintenance of Parking Lots and Sidewalks training class.
  • A review of the species, community, and ecosystem impacts of road salt salinisation in fresh waters.[33].
    • This study of the impacts of road salt on local ecosystems by Hintz and Relyea (2019), found that road salts negatively affect species at all trophic levels, from biofilms to fish species but the concentration of road salt where adverse effects were observed varied and the effects themselves ranged from reductions in fecundity, size and shape to alterations to nutrient and energy flow at an ecosystem level and increased greenhouse gas emissions from contaminated wetlands and altered hydrology and oxygen, nitrogen and carbon level dynamics in lakes and streams. Concentrations at which road salt triggered an effect varied considerably. To read more about their findings, click the link above.
  • Hamilton Salt Management Plan[43].
    • The City of Hamilton's 2021 Salt Management Plan is intended to set out a policy and procedural framework for ensuring that the City continuously improves the management of road salt used in its winter maintenance operations. The plan is dynamic and allows the City to phase in new approaches and technologies in a way that is responsive to fiscal demands and the need to ensure that roadway safety is not compromised. To read more about the City's finalized plan that compares it's current practices to BMPs, opportunities for improvement, and achievement metrics which can be replicated for other Ontario municipalities, click the link above.

Proprietary Systems[edit]

In our effort to make this guide as functional as possible, we have decided to include proprietary systems and links to manufacturers websites. Inclusion of such links does not constitute endorsement by the Sustainable Technologies Evaluation Program.

  • Camion™ - Salt brine holding tank systems for liquid salt brine storage.

References[edit]

  1. 1.0 1.1 LSRCA. 2018. Parking Lot Design Guidelines: Municipal Policy Templates to Promote Salt Reduction in Parking Lots. https://www.lsrca.on.ca/Shared%20Documents/Parking-Lot-Design-Guidelines/Parking%20Lot%20Design%20Guidelines.pdf.
  2. Hossain, S.K., Fu, L. and Lake, R., 2015. Field evaluation of the performance of alternative deicers for winter maintenance of transportation facilities. Canadian Journal of Civil Engineering, 42(7), pp.437-448. https://cdnsciencepub.com/doi/abs/10.1139/cjce-2014-0423
  3. Hintz, W.D. and Relyea, R.A. 2019. A review of the species, community, and ecosystem impacts of road salt salinisation in fresh waters. Freshwater biology, 64(6), pp.1081-1097. https://www.researchgate.net/publication/331991752_A_review_of_the_species_community_and_ecosystem_impacts_of_road_salt_salinisation_in_fresh_waters
  4. Lambert, M.R., Stoler, A.B., Smylie, M.S., Relyea, R.A. and Skelly, D.K. 2017. Interactive effects of road salt and leaf litter on wood frog sex ratios and sexual size dimorphism. Canadian Journal of Fisheries and Aquatic Sciences, 74(2), pp.141-146. https://tspace.library.utoronto.ca/bitstream/1807/74970/1/cjfas-2016-0324.pdf
  5. Norrström, A.C., Bergstedt, E. 2001. The impact of sodium from de-icing salts on colloid dispersion and base cation pools in roadside soils. Water Air and Soil Pollution. Vol. 127. pp. 281-299. https://www.researchgate.net/publication/226123793_The_Impact_of_Road_De-Icing_Salts_NaCl_on_Colloid_Dispersion_and_Base_Cation_Pools_in_Roadside_Soils
  6. Norrström, A.C. 2005. Metal mobility by de-icing salt from an infiltration trench for highway runoff. Applied Geochemistry. Vol. 20, pp. 1907-1919. https://www.researchgate.net/publication/248337128_Norrstrom_A_C_Metal_mobility_by_de-icing_salt_from_an_infiltration_trench_for_highway_runoff_Applied_Geochemistry_20_1907-1919
  7. Shannon, T.P., Ahler, S.J., Mathers, A., Ziter, C.D. and Dugan, H.A., 2020. Road salt impact on soil electrical conductivity across an urban landscape. Journal of Urban Ecology, 6(1), p.juaa006. https://academic.oup.com/jue/article/6/1/juaa006/5741239?login=true
  8. Fay., L. and Shi., X. (2012). Environmental Impacts of Chemicals for Snow and Ice Control: State of the Knowledge. Water Air Soil Pollut 223:2751–2770. http://www.dot.state.mn.us/research/RFP/Lit/LS526a.pdf
  9. Bollinger, T.K., Mineau, P. and Wickstrom, M.L., 2005. Toxicity of sodium chloride to house sparrows (Passer domesticus). Journal of wildlife diseases, 41(2), pp.363-370. https://bioone.org/journals/Journal-of-Wildlife-Diseases/volume-41/issue-2/0090-3558-41.2.363/TOXICITY-OF-SODIUM-CHLORIDE-TO-HOUSE-SPARROWS-PASSER-DOMESTICUS/10.7589/0090-3558-41.2.363.pdf
  10. Shi, X., M. Akin, T. Pan, L. Fay, Y. Liu and Z. Yang (2009). Deicer Impacts on Pavement Materials: Introduction and Recent Developments. Open Civil Engineering Journal 3. https://opencivilengineeringjournal.com/VOLUME/3/PAGE/16/FULLTEXT/
  11. Shi, X., L. Fay, Z. X. Yang, T. A. Nguyen and Y. J. Liu (2009). Corrosion of Deicers to Metals in Transportation Infrastructure: Introduction and Recent Developments. Corrosion Reviews 27(1-2): 23-52. https://westerntransportationinstitute.org/wp-content/uploads/2016/08/4W1095_Intro_Developments.pdf
  12. 12.0 12.1 TRCA. 2021. Spatial Patterns (2016-2020) and Temporal Trends (1966-2020) in Stream Water Quality across TRCA’s Jurisdiction. Prepared by Watershed Planning and Ecosystem Science. October, 2021. https://trcaca.s3.ca-central 1.amazonaws.com/app/uploads/2021/10/29113334/2016-2020-SWQ-Report-v11_FINAL_AODA-FA.pdf
  13. Environment Canada and Health Canada. 2001. PRIORITY SUBSTANCES LIST ASSESSMENT REPORT. Road Salts. Canadian Environmental Protection Act, 1999. Environment Canada and Health Canada. https://www.canada.ca/content/dam/hc-sc/migration/hc-sc/ewh-semt/alt_formats/hecs-sesc/pdf/pubs/contaminants/psl2-lsp2/road_salt_sels_voirie/road_salt_sels_voirie-eng.pdf
  14. Canadian Environmental Protection Act. 1999. Environment Canada and Health Canada, Ottawa, Ontario. https://laws-lois.justice.gc.ca/eng/acts/c-15.31/FullText.html
  15. Environment Canada. 2004. Code of Practice for the Environmental Management of Road Salts. Canadian Environmental Protection Act, 1999 (CEPA 1999). April 2004. EPS 1/CC/5. https://publications.gc.ca/collections/collection_2012/ec/En49-31-1-5-eng.pdf
  16. Transportation Association Canada (TAC). 2013. Syntheses of Best Practices Road Salt Management - Salt Management Plans. April 2013. https://sustainabletechnologies.ca/app/uploads/2022/02/roadsalt-tac-full-doc.pdf
  17. Canadian Council of Ministers of the Environment. 2011. Canadian water quality guidelines for the protection of aquatic life: Chloride. In: Canadian environmental quality guidelines, 1999, Canadian Council of Ministers of the Environment, Winnipeg. https://sustainabletechnologies.ca/app/uploads/2014/05/CWQG_chlorides.pdf
  18. Health Canada. 2020. Guidelines for Canadian Drinking Water Quality Summary Table. In collaboration with the Federal-Provincial-Territorial Committee on Drinking Water of the Federal-Provincial-Territorial Committee on Health and the Environment. September 2020. https://www.canada.ca/content/dam/hc-sc/migration/hc-sc/ewh-semt/alt_formats/pdf/pubs/water-eau/sum_guide-res_recom/summary-table-EN-2020-02-11.pdf
  19. Wallace, A., Hitch, C., Ruppert, J., Chomicki, K., Cartwright, L., and VanSeters, T. 2022. Freshwater Salinization. Water Canada. January/February 2022. WC122. Digital. https://cdn.watercanada.net/wp-content/uploads/2022/01/17161341/WC122_JanFeb2022_DIGITAL.pdf
  20. 20.0 20.1 LSRCA. 2020. Friction and Parking Lots. Technical Bulletin, Volume 3 September 2020. https://sustainabletechnologies.ca/app/uploads/2021/05/Friction-and-Parking-Lots.pdf
  21. 21.0 21.1 21.2 Van Seters, T. 2022. Review of Snow and Ice Control Practices on Parking Lots and Walkways. Toronto and Region Conservation Authority, Sustainable Technologies Evaluation Program. Ontario. https://sustainabletechnologies.ca/app/uploads/2022/04/Snow-and-Ice-Control-BMPs-for-Parking-lots-and-Sidewalks.pdf
  22. Transportation Association of Canada (TAC). 2013. Syntheses of Best Practices Road Salt Management. April 2013. https://www.tac-atc.ca/sites/tac-atc.ca/files/site/doc/resources/roadsalt-1.pdf
  23. Clear Roads. 2022. Research by Topic. Accessed - May 16 2022: https://clearroads.org/research-by-topic/
  24. 24.0 24.1 STEP. 2019. Procurement Guidance for Parking Lot Snow and Ice Management. Version 2.0 https://sustainabletechnologies.ca/app/uploads/2019/06/Procurement-Guidance-Parking-Lot-Snow-and-Ice-Mgmt.pdf
  25. 25.0 25.1 Kennaley, R. 2021. Legislative solutions to slip and fall liability - Ontario’s Bill 118 marks huge step in the right direction. Landscape Ontario. Accessed - May 8 2022: https://landscapeontario.com/legislative-solutions-to-slip-and-fall-liability
  26. LSRCA. 2018. Parking Lot Design Guidelines - Municipal Policy Templates to Promote Salt Reduction in Parking Lots. https://www.lsrca.on.ca/Shared%20Documents/Parking-Lot-Design-Guidelines/Parking%20Lot%20Design%20Guidelines.pdf
  27. STEP. 2020. Alternatives to Salt: What else melts snow and ice? Technical Brief. https://sustainabletechnologies.ca/app/uploads/2020/03/Alternatives-to-salt-technical-brief.pdf
  28. 28.0 28.1 28.2 28.3 28.4 Lake Simcoe Region Conservation Authority. 2017. Parking Lot Design Guidelines to Promote Salt Reduction. GHD|11115623|Report No. 2| February 22 2017. https://www.lsrca.on.ca/Shared%20Documents/Parking-Lot-Design-Guidelines/Parking-Lot-Guidelines-Salt-Reduction.pdf
  29. Ontario Provincial Standard Specification. (2014). Construction Specification and for Seed and Cover OPSS.PROV 804. Retrieved from http://www.raqsb.mto.gov.on.ca/techpubs/ops.nsf/0/3a785d2f480f9349852580820062910a/$FILE/OPSS.PROV 804 Nov2014.pdf
  30. Camion™. 2022. Brine Storage Tank. Accessed 28 Mar. 2022. https://www.camionsystems.com/product/brine-storage-tank/
  31. LSRCA. 2015.Parking Lot Design Guidelines to Promote Salt Reduction. GHD. 11115623 (2). https://www.lsrca.on.ca/Shared%20Documents/Parking-Lot-Design-Guidelines/Parking-Lot-Guidelines-Salt-Reduction.pdf
  32. Oswald, 2021. Road salt reduction on Ryerson University campus. Information Sheet. Presentation by C. Oswald at the Ottawa Riverkeeper salt management forum in April 2021. Ottawa Riverkeeper. January 18, 2022. Accessed May 16 2022. https://ottawariverkeeper.ca/2021-2022-road-salt/
  33. 33.0 33.1 Hintz, W.D. and Relyea, R.A. 2019. A review of the species, community, and ecosystem impacts of road salt salinisation in fresh waters. Freshwater biology, 64(6), pp.1081-1097. https://www.researchgate.net/publication/331991752_A_review_of_the_species_community_and_ecosystem_impacts_of_road_salt_salinisation_in_fresh_waters
  34. : Murison, L., Oswald, C., Gillion, E., and International Landscaping Inc. 2022. Salt Management - Partnership and Outreach Update. https://pub-peelregion.escribemeetings.com/filestream.ashx?DocumentId=9868.
  35. Region of Waterloo. 2020. Salt reduction partnership. Region of Waterloo, Water Services. https://www.regionofwaterloo.ca/en/living-here/resources/Documents/water/was-protect_closed_sign_program.PDF
  36. STEP. 2019. Salt Application Best Practices for Winter Maintenance Contracts. Technical Brief. https://sustainabletechnologies.ca/app/uploads/2019/06/Salt-application-best-practices-for-winter-maintenance-contracts-brochure.pdf
  37. Marvin, J.T., Scott, J., Van Seters, T., Bowers, R. and Drake, J.A. 2021. Winter Maintenance of Permeable Interlocking Concrete Pavement: Evaluating Opportunities to Reduce Road Salt Pollution and Improve Winter Safety. Transportation Research Record, 2675(2), pp.174-186. https://journals.sagepub.com/doi/abs/10.1177/0361198120957320
  38. Smart About Salt Council (SASC). n.d. Smart About Salt: Winter Salt Management Program. http://www.smartaboutsalt.com/
  39. Smart About Salt Council (SASC). n.d. Smart About Salt: Winter Salt Management Program. http://www.smartaboutsalt.com/
  40. STEP. 2016. Salt Application Verified Equipment Program: Managing Risk While Saving Money. Brief. https://sustainabletechnologies.ca/app/uploads/2016/01/Salt-brochures-v11.pdf
  41. Conservation Ontario and Ontario Good Roads Assn. 2018. Good Practices for Winter Maintenance in Salt Vulnerable Areas. June, 2018. https://conservationontario.ca/fileadmin/pdf/conservation_authorities_section/SWP_Combined_SVA_Document.pdf
  42. Minnesota Pollution Control Agency. 2015. Winter Parking Lot and Sidewalk Maintenance Manual: Reducing Environmental Impacts of Chloride. Third Revision. p-tr1-10. https://www.pca.state.mn.us/sites/default/files/p-tr1-10.pdf.
  43. City of Hamilton. 2021. 2021 Salt Management Plan. https://www.hamilton.ca/sites/default/files/media/browser/2022-01-17/coh-salt-management-plan2021.pdf

Lake Simcoe Region Conservation Authority

Refers to the conditions in which an organism lives and survives or the conditions in which an organism resides. These conditions can be described as aspects of a “physical”, “social” or an “economic” environment, depending on the perspective perceived by the observer.

Refers to the conditions in which an organism lives and survives or the conditions in which an organism resides. These conditions can be described as aspects of a “physical”, “social” or an “economic” environment, depending on the perspective perceived by the observer.

Low Impact Development. A stormwater management strategy that seeks to mitigate the impacts of increased urban runoff and stormwater pollution by managing it as close to its source as possible. It comprises a set of site design approaches and small scale stormwater management practices that promote the use of natural systems for infiltration and evapotranspiration, and rainwater harvesting.

The portion of water precipitated onto a catchment area, which then flows as surface discharge from the catchment area past a specified point.

Water from rain, snow melt, or irrigation that flows over the land surface.

The slow movement of water into or through a soil or drainage system.

Penetration of water through the ground surface.

Toronto and Region Conservation Authority

State of the art methods or techniques used to manage the quantity and improve the quality of wet weather flow. BMPs include Source, Conveyance and End-Of-Pipe Controls.

Land owned by private individuals or companies.

A biological community, including humans and their natural environment.

Best management practice. State of the art methods or techniques used to manage the quantity and improve the quality of wet weather flow. BMPs include: source, conveyance and end-of-pipe controls.

Sustainable Technologies Evaluation Program

A mixture of mineral aggregates bound with bituminous materials, used in the construction and maintenance of paved surfaces.

Layer of rock or soil that holds or transmits water.

Watercourses and Lake Ontario, to which Stormwater and Combined Sewer Overflows discharge.

The portion of water precipitated onto a catchment area, which then flows as surface discharge from the catchment area past a specified point.

Water from rain, snow melt, or irrigation that flows over the land surface.

The total mass of a pollutant entering a waterbody over a defined time period.

The net amount of something (e.g. chemical, such as phosphorus), calculated as the product of concentration and volume in a given time. Some BMPs significantly reduce loading of pollutants to the environment by reducing volume more so than concentration.

A vegetated ecosystem alongside a waterbody, characteristically have a high water table and are subject to periodic flooding.

Any form of rain or snow.

Natural or artificial means of intercepting and removing surface or subsurface water (usually by gravity).

Mineral particles which are smaller than 2 mm, and which are free of appreciable quantities of clay and silt. Coarse sand usually designates sand grains with particle size between 0.2 and 0.02 mm.

A hard surface area (e.g., road, parking area or rooftop) that prevents or retards the infiltration of water into the soil.

The water below the surface, and typically below the groundwater table.

A body of water smaller than a lake, often artificially formed.

a gently sloping, densely vegetated areas that treat runoff as sheet flow from adjacent impervious areas. They function by slowing runoff velocity and filtering out suspended sediment and associated pollutants, and by providing some infiltration into underlying soils.

A stormwater management strategy that seeks to mitigate the impacts of increased urban runoff and stormwater pollution by managing it as close to its source as possible. It comprises a set of site design approaches and small scale stormwater management practices that promote the use of natural systems for infiltration and evapotranspiration, and rainwater harvesting.

A broad category of particulate material used in construction, including sand, gravel, crushed stone, slag, recycled concrete and geosynthetic aggregates, and available in various particulate size gradations.

The delivery of a disproportionately large load of pollutants during the early part of storms due to the rapid runoff of accumulated pollutants. The first flush of runoff has been defined several ways (e.g., 10 mm per impervious area).

Initial pulse of stormwater runoff which picks up the pollutants that have settled on surfaces during the dry period. The first flush contains the highest pollutant concentrations.

An alternative practice to traditional impervious pavement, prevents the generation of runoff by allowing precipitation falling on the surface to infiltrate through the surface course into an underlying stone reservoir and, where suitable conditions exist, into the native soil.

A vegetated area such as a bog, fen, marsh, or swamp, where the soil or root zone is saturated for part of the year.

A biological community, including humans and their natural environment.

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