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Low Impact Development

​Low Impact Development (LID)

is a stormwater management approach that works with nature to manage rainwater as close to where it falls as possible by managing water on your own site, focusing on slowing rainwater down, controlling the quantity and flow of stormwater, soaking it up, and using soil and plants to clean it.

Slowing the water limits erosion and runoff of polluted water, filters it, and keeps water usable onsite

What is Stormwater runoff?

Stormwater runoff is rain or snowmelt when it flows over land or paved surfaces and is not absorbed into the ground. 

The Problem with Runoff

As water runoff flows across the ground's surfaces, it picks up what it touches. The further over land runoff travels, the more polluted it becomes.

Unless something intercepts it, the runoff carries dirt, chemicals, and other pollutants directly to our streams and waterways.

The other Problem; there's too much runoff

As we build more roads, houses, and other hard surfaces, less water is able to be absorbed into the soil and underground aquafers, so more and more water is running across the surface. The increase of surface water Runoff can be a powerful thing, causing erosion and flooding damage.

What is a watershed?

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Every site that is not perfectly flat and perfectly level is a watershed

(the land area down which all water flows). 

All land on earth is a watershed 

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The amount of area covered by plants affects the amount of water that will infiltrate the soil.
Greater impervious areas (like roads, roofs, and parking lots) result in greater amounts of water runoff.

Plants slow the flow of water and increase the permeability of the soil. 

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When it rains in the forest, most of the water evaporates or is absorbed into the ground where it recharges groundwater or is taken up by the roots of the plants and trees. Allowing water to filter through the ground naturally, removes many of the pollutants in the water before it reaches our rivers, lakes, and marine waters.

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Traditional Stormwater management (also called "gray infrastructure")

channels runoff from the site as quickly as possible. When our stormwater management process was originally created, the main concern was the potential damage to structures, so the focus was to direct runoff away from roads, buildings, and structures quickly.

Unfortunately, this type of management results in too much water, flowing along, picking up contaminants, flooding rivers, and polluting all our waterways. The gray infrastructure in many areas is aging, and it doesn't have the capacity to manage large volumes of stormwater.

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Low-Impact Development (LID) (also called "green infrastructure")

is designed to mimic the natural hydrologic functions of a site.

Slowing the runoff, allows the water to filter into the soil which reduces the amount of runoff eroding land and picking up pollutants, which reduces the amount of pollutants that end up in our waterways.

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The Good News!

Not only do these techniques improve water quality, restore ground water reserves, and create a healthier yard, but many of these techniques are easily accomplished, beautiful, and low maintenance additions to our homes that don't require any extra cost, just a different plan. 

The Solution

Slow the flow of water, so it can be soaked into and filtered through the soil.

Water is an important resource; we shouldn't let it run amuck. 

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The Basics of LID

  • Minimize site disturbance and protect native soils and vegetation (Don't remove native trees and shrubs unnecessarily. Do not disturb or compact soil unnecessarily.)

  • Use on-site natural features (Let the site work for you.)

  • Manage stormwater close to the source (don’t let the water leave the site).

  • Distributed stormwater Best Management Practices (BMPs) (Use BMPs effectively throughout the site.)

rainscape brochure
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Low Impact Development promotes the view of rainwater as a resource to be preserved and protected, not a nuisance to be eliminated. 

When implemented broadly, LID can mitigate the urban heat island effect, save energy, reduce air and water pollution, improve neighborhood aesthetics, increase groundwater recharge, and increase habitat for wildlife, such as birds and pollinators.

Q. Is it true that LID practices don't work in areas that receive large volume storms?

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A. No. read more...

LID is economical

LID is as cost-effective as—if not more cost-effective than—conventional approaches in part because of the long term savings in maintenance and repair. Not to mention the aesthetic benefits.

 

Raingardens attract dragonflies, frogs, and birds

Water in a properly designed rain garden will not last more than 2 days after most storms which is not long enough for mosquitoes to use, but it will be enjoyed by many of our wild friends.

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Rain gardens are designed to be self-sufficient

Some weeding and watering will be needed in the first two years, and perhaps some thinning in later years as the plants mature, but a well-planned raingarden can be maintained with little effort after the plants are established.

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Why aren't more people using LID techniques?

I don't know! Maybe they haven't heard about them yet.  We need to spread the word!

LID Techniques Can Be Applied at Any Development Stage

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•   In undeveloped areas, an LID design can be incorporated in the early planning stages. Typical new construction LID techniques include protecting open spaces and natural areas such as wetlands, installing bioretention areas (vegetated depressions) and reducing the amount of pavement.

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•   In developed areas, communities can add LID practices to solve problems and provide benefits such as being used to buffer structures from roads, enhance privacy among residences, and for an aesthetic site feature.  Typical post-development LID practices range from directing roof drainage to an attractive rain garden to retrofitting streets with features that capture and infiltrate rainwater

Roadtrip

Site Assessment

  • Draw the general layout of your site (graph paper helps). Include hard surfaces such as buildings and pavement as well as important features such as powerlines, underground utilities, and easements.

  • Add impervious areas like the driveway, sidewalks, or parking areas.

  • Measure the length and width, then multiply the two together to get the area. Estimate hard, or impervious areas where water runs off and note the measurements on the map.

  • Locate the downspouts that drain water from your roof and mark them on your map. Note the rooflines and area draining to the downspout.

  • Look at other impervious surfaces on your site. Try to figure out where runoff from these areas goes. If it isn’t raining, use a hose. Use arrows to note on your map the direction the water flows. 

  • Look at other surfaces of your property and mark any noticeable hills and dips. Note areas that stay wet and muddy. Note areas where water soaks in or are soft (lawns, planting beds, trees).

  • Soil type has a lot to do with how well rainwater soaks into the ground. Sandy, loamy soil soaks up water very quickly. Heavier soils with clay don’t soak up water as well. 

  • Be aware of municipal permitting and requirements and the effect your project may cause your neighbors.

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Evaluate Your Site Assessment Map

The goal is to direct stormwater towards water storage areas or those surfaces which soak up rain

such as vegetated surfaces like rain gardens or other garden areas.  If the space is too small, a rain harvesting practice, such as a rain barrel can be used. You may need to reroute drainage systems to get water to where there is enough space to install a particular practice. What is possible depends onsite conditions, set back requirements, sizing, and soil constraints. 

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Sketch Some Ideas and Take Action
In this Example of Plan, they have decided to install rain barrels at 3 downspouts and a rain garden at the fourth.  Along with directing rain water across driveway into second rain garden, they plan to install gutters and downspouts on garage. One drains to rain barrel, one drains to a rain garden. The more area where excess lawn is replaced with flowers, shrubs, and trees, the more water will be absorbed into the ground in a useful way.

NOTE:

All development within the special flood hazard areas (SFHA) must incorporate low impact development techniques where feasible to minimize or avoid stormwater effects. With various elements of low impact development (LID), most projects on parcels ½ acre in size or larger in rural areas can often meet these requirements by using dispersion as follows:

LID  Dispersion worksheet

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LID Construction Techniques

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  • Conserve natural areas wherever possible (Don't remove native trees and shrubs unnecessarily.)

  • Minimize the development impact on hydrology (Do not disturb or compact soil unnecessarily.

  • Maintain runoff rate and duration from the site (don’t let the water leave the site).

  • Distributed stormwater Best Management Practices (BMPs) (Use BMPs effectively throughout the site.)

  • Implement pollution prevention and proper maintenance.

Help your landscape to work for you.

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  • Retain trees and other vegetation which intercept precipitation with the tree canopy, leaves, and roots. 

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  • Grade only as much of the land as needed so soil, terrain, and plants can slow runoff and hold water until it is absorbed into the soil. 

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  • Disperse water by directing runoff from roofs, pavements, and similar impervious surfaces to rain catchments or planted areas that can benefit from the water. 

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  • Create beautiful and useful outdoor spaces that limit lawn and other compacted areas while maintaining soil that can absorb water. 

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  • Place driveways and parking areas thoughtfully to limit compacted soil and direct runoff to planted areas.

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  • Use natural mulch to improve soil's ability to absorb and filter water.

Site Planning Tips 
to minimize the impact the construction project will have on the patterns of water flow and vegetated areas of the site and help facilitate stormwater infiltration on the property: 

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  • Place structures as close to the public access point as possible to minimize road/driveway length. Minimize paved parking areas and utilize porous paving options wherever possible. 

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  • Slope paved areas to facilitate drainage to stormwater management areas. 

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  • Reduce building footprints whenever possible. Utilize basements or taller structures with lofts or second stories to achieve square footage goals. 

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  • Orient buildings on slopes with long-axis along topographic contours to reduce grading requirements. 

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  • Set clearing limits that give maximum protection to soils and vegetation while allowing reasonable areas for equipment to maneuver on the site. Delineate the areas both on the construction plans and on the ground with temporary fencing or taping. 

Depending on the soil type that you have, your water movement will be affected in certain ways. If your soil is predominantly sand, you are not likely to have flood issues, but may struggle to retain water, because sand’s large particles let water through easily. If you have predominantly clay soil, your soil’s tiny particles hold water very easily, become waterlogged quickly, and then tend to let water run off the surface thereafter.

 

Developing a Drainage Plan 

1. Conduct a site inventory to determine existing patterns of water movement and vegetated areas on your site. Consider ways your proposed development can avoid impacts to them. 


2. Obtain an accurate topographic map for the site to use as a basis for the drainage plan. This can be as simple as a map that denotes flat areas, sloped areas with approximate percent grade, and drainage paths. Topographic information for your site can be found on the Skagit County imap. 

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3. Find out the soil type on your project site in order to determine which stormwater management techniques will be applicable for your site

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When properly designed and constructed, a drainage plan protects the environment, property owners, and neighboring properties from adverse impacts related to residential development.

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Seeking on site areas that infiltrate well will lead to the most cost-effective designs. Effective siting identifies soil variability and includes doing some initial infiltration rate testing for planning phases. 

Engineered Systems


•    Engineered systems that filter storm water from parking lots and impervious surfaces, such as bioretention cells, filter strips, and tree box filters


•    Engineered systems that retain (or store) storm water and slowly infiltrate water, such as sub-surface collection facilities under parking lots, bioretention cells, and infiltration trenches


•    Pervious, permeable, and porous surfaces that allow drainage between impervious surfaces such as porous concrete, permeable pavers, or site furnishings made of recycled waste

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•    Remove curbs and gutters from streets and parking areas to allow storm water to "sheet flow" into vegetated areas.

Low-tech Systems

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•    Native or site-appropriate vegetation.

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•    Low-tech vegetated areas that filter, direct, and retain storm water such as hedgerows, rain gardens, and bio-swales


•    Pervious, permeable, and porous surfaces that help break up (disconnect) impervious surfaces such as porous concrete, permeable pavers, or site furnishings made of recycled waste


•    Water collection systems such as subsurface collection facilities, cisterns, or rain barrels

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•    Shape driveways, parking areas, and Landscape areas to allow storm water to "sheet flow" into vegetated areas.

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Downspouts
can be directed to a water catchment system or directed to areas such as a rain garden, planted area, or gravel filled trenches, where it can be absorbed. 

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Rain dispersal systems spread out the flow of water from impervious surfaces.

Spreading out the water reduces the force hitting the soil, allowing it to slow down and be absorbed into the soil.

Rainwater Dispersion

Driveways, sidewalks, etc.
can be sloped to shed water into areas such as a rain garden, planted areas, etc

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Rainwater Catchment
Also known as rainwater harvesting or rainwater collection, it is the simple act of collecting the rainwater that runs off the hardscapes on your site for beneficial use.

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Residents of Washington state may harvest rainwater without a permit as long as:

  • it's used on the property from which it was collected

  • it's collected on an existing rooftop

 

Washington state law even authorizes counties to reduce rates for

stormwater control facilities that utilize rainwater harvesting. Wash. Rev. Code §36.89.080.

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More...

Rainwater collection is legal in the State of Washington

Passive methods for rainwater harvesting, include infiltration basins, bio-swales, etc. that slow or stop the flow of runoff across your site. These allow stormwater to infiltrate into the ground, hydrating soils and recharging groundwater.

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Active

Active rainwater harvesting catches and stores the water in one or more containers, such as barrels or cisterns for later use.  With active rainwater harvesting, you control when, where, and how the water is used.

Passive

Rainwater harvesting makes the most of your resources;

managing water that would, at best, be wasted and, at worse, be destructive and directing it to where it can be a useful and cost-effective resource. 

During the summer months it is estimated that nearly 40 percent of household water is used for lawn and garden maintenance. A rain barrel collects water and stores it for those times that you need it most — during the dry summer months. Using rain barrels potentially helps homeowners lower water bills, while also improving the vitality of plants, flowers, trees, and lawns.

The average rainfall of one inch within a 24-hour period can produce more than 700 gallons of water that runs off the roof of a typical house.

Harvesting rainwater doesn't have to be a big project. It can just be one rain barrel attached to one gutter that provides convenient water for the chicken yard or for watering a flowerbed without having to drag a hose, etc.

Small systems work fine and expanding your system is fairly easy. Start by deciding how much water you are hoping to store and where you want to locate it. Placing the barrel higher up than anywhere the water will be used allows the use gravity instead of a pump.

It is best if barrels block out any light that could enter them, to avoid growth of pathogens inside the water.

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Natural Pond
Top

LID Landscaping (Rainscaping)

Plants are an Effective L.I.D. Resource. 

The amount of area covered by plants affects the amount of water that will infiltrate the soil.
Greater impervious areas (like roads, roofs, and parking lots) result in greater amounts of water runoff.

 

Rainscaping is a way to manage water on your own site, by allowing the land and plants to slow rainwater down, controlling the quantity and flow of stormwater. Plants slow the flow of water and increase the permeability of the soil enabling it to soak up water and clean it.

 

Slowing the water down limits erosion and keeps water usable onsite.

Plants Reduce Energy & Maintenance Costs

​Shade from trees keeps homes and yards cooler in the summer.

In the winter, Trees and shrubs slow the wind and reduce wind chill. 

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Ground covering plants reduce the amount of water evaporating from the soil which therefore requires less water.

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Soil effectively covered by plants, shades out weed seeds, so requires less maintenance than landscape with exposed soil.

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Plants protect the soil from wind and water erosion and reduce the amount of pollutants that enter our waterways.

Turf grass vs other vegetation

While turf grass is better than pavement at allowing water to infiltrate into the soil, research has demonstrated that areas covered with turf grass control much less water than other vegetation. Therefore, in keeping with the goals of nonstructural LID s, the amount of lawns and other grass areas at land development sites should be minimized. The use of plants can provide a low-maintenance alternative to turf grass, resulting in lower fertilizer and water needs. The use of native ground cover, shrubs, and trees instead of turf grass can create infiltration characteristics similar to those of natural areas. 

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Consider reducing the size of excessive lawns. Changes can be made gradually over several seasons.


An easy way to start is by expanding areas already established with shrubs and trees. 

Expand the width and include ground covers, xeriscape plantings, perennial flower beds, and/ or tiered shrub plantings.

Convert areas that are difficult to mow, such as corners, edges, and under trees.

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Vegetated areas provide a pervious surface for groundwater recharge and can remove pollutants from the runoff flowing through it. Installing or maintaining a strip of plants at the edge of an area, whose purpose is to slow surface water runoff, to assist in infiltration, and prevent soil erosion is an effective and easy way to maintain a healthy landscape.

Rolling hills with a patchwork of crop fields, some golden and some green surrounded by hedgerows of trees and shrubs.
Looking down a single, young hedgerow  with a douglas spirea in the forground.
A manicured landscape of lawn winding through berms filled with trees, shrubs, and groundcover plants.

Hedgerow, Filter strip, or Vegetated buffer 

Filter strip
A raingarden filled with flowering plants, surrounded by a mowed lawn next to the curb of the road.

There are many ways plants can be effectively used in the landscape, but plant selection and proper planting and care are vital.

Select plants. Include native plant species that provide food and habitat for wildlife and insect pollinators. Native plants are naturally adapted to local growing conditions. They require less water, fertilizer, and maintenance. Native plants are also known to be very effective in managing storm water because many species have deep root systems which stabilize soil and facilitate the infiltration of storm water runoff. These plants evolved and adapted to the local climate and growing conditions. Adding even just a few native plants to your landscape can go a long way towards supporting wildlife.

Select a mix of plants with different foliage, texture, and flowers that bloom at different times for season. 

New plantings require extra care during the first 1-3 years. 

Make sure new plants receive a deep watering 1 or 2 times per week for the first several months and then at least once per week for the first year.

Good maintenance while the garden is becoming established is important. Pull weeds while they're young, before they've gone to seed. Replace any dead plants to fill in holes. A full coverage of plants, like mulch, helps maintain soil moisture, prevent erosion, and reduce weeds.

Once native plants are established, they need little maintenance to perform well and look good. 

Young native plants in a freshly planted flower bed.
Gardentips
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If the garden is near the road, consider sight lines and setbacks

A raingarden filled with flowering plants, surrounded by a mowed lawn next to the curb of the road.
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Edging (such as pavers, stones, etc.) can facilitate access for maintenance and provide separation from lawn and other landscaped areas.

To maintain access to the middle of the garden for weeding and other tasks. A few strategically placed flat rocks or pavers can allow access without compacting the soil or leaving room for weeds.
 

The preservation of existing natural vegetated areas is a nonstructural LID-BMP that should be considered

throughout the design of a land development.  Ideally, the more natural area to be preserved, the better.

 

Using plants as a nonstructural LID technique can significantly reduce the impact of rainwater.  

Vegetated areas provide a pervious surface for groundwater recharge, particularly during dormant or non-growing seasons. In addition, vegetation can remove pollutants from the runoff flowing through it.

Vegetative filters and buffers can be created by preserving existing vegetated areas over which runoff will flow or by planting new vegetation.

Vegetative filters located immediately downstream of impervious surfaces such as roadways and parking lots can achieve pollutant removal, groundwater recharge, and runoff volume reduction.

Vegetated buffers adjacent to streams, creeks, and other waterways and water bodies can also help mitigate thermal runoff impacts, provide wildlife habitat, and increase site aesthetics.

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Rain gardens

A rain garden is a landscaped depression in the land, with soil designed to help rainwater runoff from a roof, driveway or other impervious surfaces to soak into the ground and filtered.

diagram of a residential rain garden

Bioretention Cells, Bioswales, and some Hedgerows are sometimes referred to as "Rain Gardens", because they are basically doing the same thing in different situations. For example, a "Bioswale" is basically a kind of rain garden where water is slowed and filtered, but much of the water is directed to another location.

Bioretention is a more complex rain garden with drainage systems and amended soils.  

Hedgerows are not technically rain gardens but can be used to slow surface water as it heads down slope, as an edge to a Bioswale, or as check dam

Curb Cut Extension

A nicely planted sidewalk median with a curb cut extention into a street with a rain garden.

Curb Cut Raingarden

A rain filled curb cut rain garden between a sidewalk and the edge of a parking area.

Curb Cut Inlet

A curb cut into a parking lot island planted with trees and shrubs

A Bioretention cell (strip or trench) is more complex rain garden with engineered drainage systems in a slightly recessed landscaped area constructed with a specialized soil mixture, an aggregate base, an underdrain, and site-appropriate plants.

A tile covered planted bioretention cell at the edge of a city street with curb cuts and safty fence.

Bioretention

bioretention system diagram
A fairly large earthen bioretention system filled with plants in an open area with grass and trees.

A bioswale is a slightly recessed landscaped area constructed downstream of a runoff source. At the beginning of a rain event, a bioswale absorbs and filters water runoff. Once the soil-plant mixture below the channel becomes saturated, the swale acts as a conveyance structure to a bioretention cell, wetland, or infiltration area.

There is a range of designs for these systems. Some swales are designed to filter pollutants and promote infiltration and others are designed with a geo-textile layer that stores the runoff for slow release into depressed open areas or an infiltration zone.

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Bioswale

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Rain gardens are designed to be self-sufficient. Some weeding and watering will be needed in the first two years, and perhaps some thinning in later years as the plants mature, but a well-planned raingarden can be maintained with little effort after the plants are established.

Include native plants!
Native plants eliminate the need for fertilizers and pesticides, and require little or no supplemental water. These plants evolved and adapted to the local climate and growing conditions. 
Native plants are important to wildlife including bees, butterflies, and birds adapted to using native plants as a source of food and shelter.  Adding even just a few native plants to your landscape can go a long way towards supporting wildlife.

Rain gardens function only as well as they are designed. Planning is needed as well as knowledge of soil and local weather conditions. Take the time to plan effectively.

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Note: Don’t locate a rain garden within 10 feet of a building foundation, near the edge of a steep slope or bluff, in low spots that do not drain well, where groundwater is within one foot of the bottom of the finished rain garden, over a septic drain field or tank, over shallow utilities (call before you dig), or in areas that would require disturbing healthy native soils and vegetation.  For more in depth information, see the online books below.

There are many ways plants can be effectively used in the landscape, but plant selection and proper planting and care are vital.

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If planting near the road, consider sight lines and setbacks

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Anatomy of a Rain garden

A diagram showing ground level and overhead view of a rain garden. Text boxes describe the 3 planting Zones.
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RAIN GARDEN DESIGN TIPS

Make it part of the landscape. It should work together with and be visually and functionally integrated into the rest of the landscape.

Choose a shape. Consider all the rules of composition, screening, and circulation—not just the rule that says to put a rain garden in a low spot 10 feet from the house.

Consider style. A rain garden can be as formal or as wild as you like, but pay attention to how it looks with your home’s facade. 

Integrate with other gardens. Consider making a depression within a perennial bed or shrub border (especially if space is tight and you don’t have room for a larger rain garden that stands alone).

Create repetition. Put in more than one rain garden for repetition and continuity. If it works with your overall design, create a little rain garden for each downspout. Or add other water features around your yard such as a fountain, birdbath, or waterfall to repeat the water theme, which is another way to lend cohesion to your landscape.

Consider aesthetics and function. Make your rain garden more attractive and user-friendly. Use decorative stones as edging, create an adjacent seating area, build an attractive pathway, or add other hardscape and accessories to make your rain garden more visually appealing.

 

RG tips

Select plants. Include native plant species that provide food and habitat for wildlife and insect pollinators. Rain garden plants should be able to tolerate moisture as well as intermittent dry spells. Include sedges, grasses, and rushes with deep root systems that will help water seep into the soil. Select a mix of plants with different foliage, texture, and flowers that bloom at different times for season-long interest. Add marginal plants that are more drought-tolerant around the perimeter. Plant shrubs in groups of 3 to 5 plants and small plants in "drifts" for greater visual impact. 

RG zones

Planting Zone

Grey sun (Shade)

Rain garden plant selection examples

Yellow Sun
A rain garden icon showing 3 area zones in black and white with the center most pond colored green , noting Zone 1
Grey Sun (Shade)

Plants for shady zone 1

Slough sedge (Carex obnupta) 
Small-fruited bulrush (Scirpus microcarpus)
May Lily (Maianthemum dilatatum)

Pacific waterleaf (Hydrophyllum tenuipes)

Ferns Lady fern (Athyrium filix-femina) 
Deer fern (Blechnum spicant)

Goat's beard (Aruncus dioicus)
Red-twig dogwood (Cornus sericea) 
Black twinberry (Lonicera involucrata)
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Yellow Sun

Plants for sunny zone 1

Dagger-leaf rush (Juncus ensifolius), Taper-Tipped rush (Juncus acuminatus)

Cascade penstemon (Penstemon serrulatus)

Henderson’s checker-mallow (Sidalcea hendersonii)

Rocky Mountain Iris (Iris missouriensis)

Red-twig dogwood (Cornus sericea)

Pacific ninebark (Physocarpus capitatus)

Black twinberry (Lonicera involucrata)

Pacific crabapple (Malus fusca)

Plants in zone 1 need to be able to tolerate wet conditions and seasonal flooding.

A rain garden icon showing 3 area zones in black and white with the zone between the center and outside edge colored green noting Zone 2
Grey Sun (Shade)

Plants for shady zone 2
May Lily (Maianthemum dilatatum)

Oregon wood sorrel (Oxalis oregana)

Sword fern (Polystichum munitum)  
Lady fern (Athyrium filix-femina)

Low Oregon Grape (Mahonia repens)
Snowberry (Symphoricarpos albus)
Salal (Gaultheria shallon)
Western Pussy Willow (Salix scouleriana)

Cascara (Frangula purshiana)

Yellow Sun

Plants for sunny zone 2
Daylily (Hemerocallis spp.) 
Giant camas (Camassia leichtlinii)

Henderson's Checker Mallow (Sidalcea hendersonii)

Douglas Iris(Iris douglasiana)
Red-twig dogwood (Cornus sericea) 
Snowberry (Symphoricarpos albus) 
Western Pussy Willow (Salix scouleriana)
Tall Oregon grape (Mahonia aquifolium)

Pacific crabapple (Malus fusca)

Plants in zone 2 need to be able to tolerate moist to occasionally flooding conditions.

A rain garden icon showing 3 area zones in black and white with the zone on the outside edge colored green noting Zone 3
Grey Sun (Shade)

Plants for shady zone 3

Inside-out flower (Vancouveria hexandra)

Western bleeding heart (Dicentra formosa)

Sword fern (Polystichum munitum)

Evergreen huckleberry (Vaccinium ovatum)

Low Oregon grape (Mahonia nervosa)

Rhododendron macrophyllum

Vine maple (Acer circinatum),

Cascara (Frangula purshiana)

Indian plum (Oemleria cerasiformis)

Yellow Sun

Plants for sunny zone 3
Black-eyed Susan (Rudbeckia hirta)

Cooley's Hedge-nettle (Stachys cooleyae)

Oceanspray (Holodiscus discolor), 
Red-flowering currant (Ribes sanguineum) 
Snowberry (Symphoricarpos albus)

Oregon Boxleaf (Paxistima myrsinites)

Tall Oregon grape (Mahonia aquifolium)  
Serviceberry (Amelanchier alnifolia), Oceanspray (Holodiscus discolor)

Mock Orange, Philadelphus lewisii

Plants in zone 3 need to be able to tolerate moist to dry conditions.

New plantings require extra care during the first 1-3 years. 

Make sure new plants receive a deep watering 1 or 2 times per week for the first several months and then at least once per week for the first year.

Good maintenance while the garden is becoming established is important.

Apply a good layer of mulch to maintain soil moisture and reduce weeds.

Once Rain gardens are established, they need little maintenance to perform well and look good. 

A newly planted rain garden in a front yard near the road.
A healthy mature rain garden in a front yard near the road.

Rain Garden Maintenance

A person wearing disposible gloves is picking up trash from a concrete gutter.

 

  • After heavy storms, check the inflow and overflow areas to make sure they are still intact and can continue to carry water into and out of the rain garden.

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  • At least twice a year, check around the inlet and overflow areas for debris build-up such as leaves, sticks, and other items. 

Keep the Flow 

Water flowing into the rain garden can carry with it various types of debris that can clog the soil mix and slow drainage. 

Fast flowing water can also slowly eat away at your soil layer, washing it away and damaging your garden.
 

RG maintenance
  • Maintain a cover of decorative rock around the inlet and overflow area to protect the soil.

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  • Look for areas where water may not be soaking into the ground. This may be due to fine sediment or compaction of the soil.

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  • Remove sediment that may be building up and rake the soil surface. If you suspect compaction, break up and loosen the soil when it is not saturated.

A curb cut rain garden with clean rocky inlet and flowing water.
a terraced garden area with fresh mulch

Maintain soil coverage​

  • Mulch provides multiple benefits for rain gardens by helping to:
    Keep the soil moist.
    Replenish organic material in the soil.
    Prevent erosion.
    Discourage weeds.

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  • Every year check the mulch layer and, if needed, apply enough to maintain a layer of shredded or chipped wood mulch that is about 3 inches deep all throughout your rain garden—on the bottom, the sides, and around the perimeter.

Maintain a healthy cover of plants

  • Replace any dead plants to fill in holes.

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Like mulch, full coverage of plants provides multiple benefits for rain gardens by helping to: 

  • Keep the soil moist. 

  • Replenish organic material in the soil. 

  • Prevent erosion. 

  • Discourage weeds

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Edging (such as pavers, stones, etc.) can facilitate access for maintenance and provide separation from lawn and other landscaped areas.

To maintain access to the middle of the garden for weeding and other tasks. A few strategically placed flat rocks or pavers can allow access without compacting the soil or leaving room for weeds.
 

Weeding

Rain gardens will still soak up and filter rain water even if they are full of weeds. However, the plants in the rain garden may not grow as well with all the competition. Soils in rain gardens have good structure, so weeds should be easy to pull by hand, especially in the spring when the soil is moist and the weeds are small.

Watering

Plants will need to be watered every few days until established (about 4 weeks). For the first year, most plants need deep watering during the dry summer season to establish healthy root systems. After two or three years the native plants in your rain garden will need little or no watering, except for during times of drought.

Fertilizing
Do not apply fertilizers

to your rain garden. The rain garden soil mix provides plenty of nutrients and the native plants in your garden are well suited to local growing conditions, so extra fertilizing is not needed.

Permeable Pavement

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Permeable pavement is a type of pavement with a porous surface that is composed of concrete, open pore pavers or asphalt with an underlying stone reservoir. It allows water to run through it rather than accumulate on it or run off of it.  The water slowly infiltrates the soil below or is drained via a drain tile. The stone or gravel acts as a natural filter and clears the water of pollutants. It is important to note that one size does not fit all - there are many pros and cons for use of each type of permeable pavements

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  • Porous Asphalt and Pervious Concrete are like conventional asphalt and concrete but with less fine aggregate content leaving open spaces for water to pass through and soak into the ground. Porous asphalt and pervious concrete are the most suitable for large areas including residential driveways and parking lots.           More...

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  • Permeable paver systems have gaps between the pavers that allow water to pass. A layer of gravel under the paver system acts as a reservoir, holding rainwater while it soaks into the ground. Pervious paver systems are the most versatile type of permeable pavement and are suitable for residential driveways, patios, and parking lots.​

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  • Turf block systems are pavers with empty spaces filled with soil and planted. Turf block systems are suitable for residential driveways. 

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When to Call a Professional
Call a professional designer if you have more vehicle traffic than a residential driveway.

Also, if your soil infiltration rate is less than 2 inches per hour, you will need to hire a designer to help you. 

Summary of Permeable Pavement Design Requirements

These site and design requirements can help you decide if permeable pavement might be appropriate for your project.

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  • Permeable pavement is allowed on surfaces with slopes no greater than 5 percent.

  • Underlying soils should have a minimum infiltration rate of 2 inches per hour.

  • There are no setback requirements for permeable pavement.  

  • There must be 5 feet between the high groundwater level and the excavated bottom.   

  • The subgrade next to structures should slope away from the structures.

  • Use a minimum of 6 inches of washed, crushed 2- to ¾-inch or No. 57 rock under concrete or asphalt.

  • Consult the Stormwater Management Manual regarding required edge restraints.

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For best results, keep in mind the following construction considerations:

  • Protect the subgrade from over-compaction during excavation.  

  • Do not excavate or compact the native subgrade in wet conditions.  

  • Consider the sequence of construction activities to protect the subgrade from traffic.

  • Protect the paving from construction traffic and sediment after installation.   

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Special Maintenance Considerations

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  • Prevent Clogging of Pavement Surface with Sediment

    • Vacuum pavement twice per year

    • Maintain planted areas adjacent to pavement

    • Immediately clean any soil deposited on pavement

    • Do not allow construction staging, soil/mulch storage, etc. on unprotected pavement surface

    • Clean inlets draining to the subsurface bed twice per year

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  • Snow/Ice Removal

    • Porous pavement systems generally perform better and require less treatment than standard pavements

    • Do not apply abrasives such as sand or cinders on or adjacent to porous pavement

    • Snow plowing is fine but should be done carefully (i.e. set the blade slightly higher than usual)

    • Salt application is acceptable, although more environmentally-benign deicers are preferable

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  • Repairs

    • Surface should never be seal-coated

    • Damaged areas less than 50 sq. ft. can be patched with porous or standard asphalt

    • Larger areas should be patched with an approved porous asphalt

LID Landscape Tips

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  • Use the shape of the land and the availability of light and water to shape your design.

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  • When you're designing a landscape, keep planting zones in mind. 

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  • Group plants together that all have the same moisture and light requirements.  

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  • Make sure plants that require a lot of water are near a water source. (Sometimes that means a hose or rain catchment)

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  • Make sure that plants that require more of your attention are easily accessible

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  • Consider the mature size of a plant.  Make sure they have room to grow and make sure that plants that require more sun are not planted next to a plant that will grow up and shade them out.​

A diagram showing ground level and overhead view of a rain garden. Text boxes describe the 3 planting Zones.
A colorful winter scene of red osier dogwood branches in the middle of  green and purple heathers and dry ornamental grasses.
  • Choose a variety of plants, including shrubs, flowers and grasses, to create variety in color, height and texture.

  • Consider the year-round look of your rain garden – clumping grasses will hold their shape throughout the winter, and many types of shrubs develop striking red branches in the colder months.

  • Consider your home’s existing landscape, and the landscaping of the surrounding neighborhood.

Tip:

The more bare ground in your garden, the more you will be fighting invasions of weeds.

Keep the soil covered by plants or adding mulch.  It will greatly reduce the amount of water transpiration, soil erosion, and weeds that will germinate in your garden, 

A wheelbarrow filled with pruned branches on a woodchip covered path between ornamental grasses and shrubs .
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