Utilize Green Infrastructure in Great Lakes Areas of Concern

Part of the reason why remediation of a legacy of industrial pollution identified as Areas of Concern (AOCs) in the St. Clair River-Detroit River corridor is taking decades to achieve is the over-reliance on concrete and steel projects where green infrastructure would be more effective.

For example, as a means of stormwater control, public and private interests in New York City (including one auto company, Toyota) determined to plant a million trees in 10 years. They achieved that goal in eight years.

In the metro Detroit area (home of three auto companies), large-scale tree planting has been forsaken out of preference for huge concrete and steel projects like the so-called retention-treatment basins (RTBs). Nevertheless, downstream pollution, including sedimentation and turbidity, continues to be problematic.

Kuhn RTB - Oakland County, Michigan

One such, the massive Kuhn RTB (formerly known as Twelve Towns) in Oakland County, recently expanded, continues to divert partially screened and treated, sediment-laden surges down the Red Run Drain to the Clinton River and on to Lake St. Clair when overwhelmed by heavy rainstorms, instead of pumping the effluent to the Detroit Wastewater Treatment Plant as usual.

Better water quality in Great Lakes AOCs can be hastened by greater reliance on green infrastructure.

Improve Lake St. Clair by Removing Floodplain Sediments

Michigan and Ontario residents alarmed about pollution in Lake St. Clair shouldn’t limit their concern to combined sewer overflows. More could be done to improve water quality upstream in the small ditches and creeks that contribute algae-fueling nutrients to rivers like the Clinton and Thames leading to the lake.

Big Spring Run - lancasteronline.com

Good results are being realized in the Chesapeake Bay watershed from the restoration of floodplains and wetlands far upstream by removing legacy sediment deposits loaded with nutrients such as phosphorus and nitrogen.

One example is a project in Lancaster County, Pennsylvania which was completed five years ago. Sediment deposits from careless land use practices in the past were removed from 12 acres of bottom land. Four and a half acres of aquatic habitat were restored and reconnected to the watershed, as well.

Sediment removed is said to have been 22,000 tons, including 25 tons of phosphorus and 30 tons of nitrogen.

“Chief among the latest findings is research showing dramatic reductions in surface water temperatures and nitrogen, the re-establishment of threatened species of plants, colonization by the green frog and a 50 percent reduction in sediment leaving the restored ecosystem.”

http://www.lancasterfarming.com/news/main_edition/chesapeake-bay-commission-tours-legacy-sediment-experiment/article_2f7d4768-cb08-5562-a70c-01548db8e8e5.html

What’s Wrong with Our Rivers? Beneficial Use Impairments

“The International Joint Commission is an independent binational organization established by the United States and Canada under the Boundary Waters Treaty of 1909….The purpose of the Commission is to help prevent and resolve disputes about the use and quality of boundary waters and to advise Canada and the United States on questions about water resources.” https://en.wikipedia.org/wiki/International_Joint_Commission

IJC has labeled bodies of water and their surroundings in the Great Lakes region which exhibit extreme environmental degradation as Areas of Concern (AOCs) in need of remediation.

[The following italicized text has been reduced by approximately 40% through editing.  The unedited text is at: http://ijc.org/en_/aoc/Desc_Impairments#sthash.swp26Pc0.dpuf ]

The 43 AOCs around the Great Lakes are the most polluted areas in the basin.  Many of the  qualities and activities which people enjoy in these waters are impaired.  The Great Lakes Water Quality Agreement focuses on 14 Beneficial Use Impairments (BUI) described below.  At least one applies to each AOC.

1. Restrictions on fish and wildlife consumption as a result of public health advisories about contaminants like mercury or polychlorinated biphenyl (PCBs) in the fish or wildlife.
2. Tainting of fish and wildlife flavor because water quality is poor, for example, by reason of excessive algae in the water.
3. Degradation of fish and wildlife populations caused by enough toxicity in the water or sediments to interfere with reproduction and growth.
4. Fish tumors or other deformities exceeding rates at comparable (but unpolluted) sites.
5. Bird or animal deformities or reproductive problems, such as cross-bill syndrome or egg-shell thinning, revealed by wildlife surveys.
6. Degradation of benthos as occurs when the community structure of sediment-dwelling aquatic insects significantly diverges from unpolluted sites of similar physical and chemical characteristics.  In benthos degraded by pollution, community structure is skewed towards insects that are  tolerant of poor water quality, and away from insects that require good water quality.
7. Restrictions on dredging activities, i. e. when contaminants in sediments exceed standards for the least restrictive disposal method, often open water disposal.
8. Eutrophication or excessive algae attributed to excessive nutrient discharges from point (end-of-pipe) or nonpoint (diffuse land uses) sources.  Typically, the impairment manifests itself as nuisance or harmful algal blooms, dissolved oxygen depletion in bottom waters, and decreased water clarity.
9. Restrictions on treated drinking water, as when contaminants still exceed human health standards, taste and odor problems are present, or additional treatment is necessary  beyond the standard in comparable locations free of offensive characteristics.
10. Beach closings required when bacterial concentrations in water commonly used for recreation, such as swimming and other water activities, exceed applicable standards.  
11. Degradation of aesthetics, as when a substance in the water produces an objectionable deposit, unnatural color or odor.  Examples include an oil slick or surface scum.
12. Added costs to agriculture or industry, such as additional treatment for livestock watering, crop irrigation, and noncontact food processing.
13. Degradation of phytoplankton (microscopic plant) and zooplankton (microscopic animal) populations reflected by community structure significantly diverging from the physical and chemical characteristics of similar but unpolluted sites.
14. Loss of fish and wildlife habitat, most commonly diminished riparian (shoreline) vegetation, coastal wetlands, or underwater fish habitat.

There are criteria to measure remediation of individual BUIs in each AOC, known as delisting criteria (sometimes numeric, sometimes narrative).  A template of delisting criteria was developed by the IJC for individual AOC committees to adapt for their own specific use, which can be found here. Several U.S. States have developed delisting criteria guidance for AOCs in their jurisdictions – see Additional Information for links to those documents.

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Beneficial Use Impairments in the Clinton River AOC:

• Restrictions on fish and wildlife consumption
• Eutrophication or undesirable algae
• Degradation of fish and wildlife populations
• Beach closings
• Degradation of aesthetics
• Degradation of benthos
• Restriction on dredging activities
• Loss of fish and wildlife habitat

https://wiki.epa.gov/watershed2/index.php/Clinton_River_Area_of_Concern

Beneficial Use Impairments in the River Rouge AOC:

• Restrictions on fish and wildlife consumption
• Eutrophication or undesirable algae
• Degradation of fish and wildlife populations
• Beach closings
• Fish tumors or other deformities
• Degradation of aesthetics
• Degradation of benthos
• Restriction on dredging activities
• Loss of fish and wildlife habitat

http://www2.epa.gov/rouge-river-aoc/about-rouge-river-aoc

DWSD and CSOs: Bad Choices, Second Chances

Heavy rainstorms cause sewer overflows that pollute lakes and streams. Attempting to control overflows in the Rouge River watershed, officials are constructing or expanding a series of impoundments called retention treatment basins that are intended to hold back a small, initial surge of polluted stormwater for subsequent primary and secondary treatment.  The remainder of the deluge is to be screened, dosed with chlorine (primary treatment) and released to the river, still laden with many pollutants.

The question raised here is whether building one or two small, full-service wastewater treatment plants in the Rouge watershed would provide greater amounts of clean water while simultaneously reducing the occasional overflows that overwhelm the massive treatment plant in Detroit at the same or even lower cost than the retention treatment basins.

Don’t confuse the following with expert analysis.  I’m struggling to understand by what reasoning federal, state and local officials think they are implementing clean water legislation concerning combined sewer overflows (CSOs) by building new or expanding existing retention treatment basins (RTBs).  It doesn’t make sense to me.

The Detroit Water and Sewerage Department (DWSD) central wastewater treatment plant is a mammoth facility intended to serve a large swath of metropolitan Detroit.  Difficulties arise when heavy rainstorms inundate the sewer system.

Major portions of metropolitan Detroit’s sewer system consist of combined sewers that carry both storm runoff and sanitary sewage.  Every time there’s a long, heavy downpour, hundreds of millions of gallons of untreated or partially treated wastewater are diverted to tributaries of Lake St. Clair and the Detroit River in order to avoid flooding basements and swamping the treatment plant.

That means that harmful levels of toxins, pathogens, nutrients and sediment contaminate natural bodies of water.

One would think that the simple solution to combined sewer overflows would be to expand the Detroit wastewater treatment plant.  There are three reasons why that wouldn’t  work:

• The plant is way too big and unmanageable already.
• There’s no more room on site.
• Detroit can’t afford it.

Several years ago, federal and state officials proposed the construction of huge tunnels to hold CSOs temporarily, but Detroit couldn’t afford that, either.

Next, city and state officials came up with a plan to build new or expand existing retention treatment basins, nine in total, in the Rouge River watershed to control CSOs.  

Each RTB would have two tanks.  After screening debris, the first tank would be filled with the initial surge of polluted stormwater, expected to contain the most pollutants (the so-called first flush), and held for eventual pumping to the Detroit plant for primary and secondary treatment.

The second tank would hold subsequent, less polluted flow, which would be chlorinated (primary treatment) and, if the inflow continued beyond the second tank’s capacity, would be discharged, still containing (1) toxins, (2) such sediment as hadn’t settled in the tank, (3) so much of the pathogens as survived the chlorine, and (4) so much of the nutrients as hadn’t clumped up with chlorination, into the Rouge River.

The cost of these nine new or expanded CSO control facilities was expected (2009) to be $479 million.

http://www.dwsdoutreach.org/Home/News/RTB_2012_23/tabid/142/Default.aspx

If each of the nine facilities diverts from the plant to the river nine million gallons per day (mgd) of partially treated overflow, that would trim the treatment plant’s overload by 91 mgd.

But wait just a minute!   An Oakland County study in 2007 suggested an intriguing series of water-related alternatives, including wastewater treatment.  

One alternative deemed cost effective was to build a new wastewater treatment plant on the Clinton River near Mound Rd., north of 22 Mile Rd.  It would reduce both normal flow to DWSD’s plant in Detroit and diversion of polluted CSOs to the Clinton River.   

The proposed plant would handle an average 52.8 mgd with a maximum of 102 mgd.  The cost was estimated (2007) at $275 million.

www.oakgov.com/water/Documents/vol_4_alternatives_analysis.pdf

A new plant like that, built on the Rouge River, would (a) not be limited to diverting partially treated stormwater from the Detroit treatment plant to the river, as would the nine RTBs, but would relieve the Detroit plant daily of up to 102 mgd, and (b) at about 60% of the cost.

Imagine the reduction of CSOs and the Detroit plant’s ordinary load if new plants as described in the Oakland study were built on both the Clinton River and the Rouge River.

Coulda, shoulda, woulda?  Why bring this up now?  Because, these are recurring opportunities. The equipment that goes into these plants takes a beating 24 hours a day, 365 days a year.  It wears out fast.  It can be repaired only so often before it has to be replaced.

As we move toward a regional water authority, we would be well advised to gradually replace segments of the Detroit wastewater treatment plant with new, smaller, more efficient and better managed treatment plants throughout the region.

Managing Silt Runoff and Sewer Overflows

Many governmental or quasi-governmental entities are responsible for water quality in southeast Michigan.  The U.S. Environmental Protection Agency (EPA) and the Michigan Department of Environmental Quality (MDEQ) oversee most of them.

In addition to regulating the Great Lakes Water Authority (GLWA) in metropolitan Detroit, EPA and MDEQ supervise overlapping responsibilities of agencies and organizations tasked with restoring degraded watersheds like those of the Clinton and Rouge rivers. [Updated January 29, 2016.]

Several decades ago, a legacy of severe and persistent pollution along the U.S.-Canadian border (including the Detroit River) led to a bi-national agreement and the designation of a number of locations as Areas of Concern (AOC), requiring extraordinary efforts to clean them up.  The Clinton River and Rouge River watersheds were among them.

Beneficial uses in these two watersheds were found to be impaired by pollution.  Organized attempts to address these concerns are called Remedial Action Plans (RAP).

Unfortunately, some of the causes of those impairments continue to this day.  For example, “Historical point source discharges and ongoing nonpoint sources are responsible for sediment contamination in the mainstream Clinton River.”

The following excerpts are from the Oakland County (MI) Water Resources Commission’s website, apparently quoting the Michigan Department of Environmental Quality (MDEQ);

“Why is erosion and sediment control important?”

“Sediment is the greatest pollutant by volume entering our lakes and streams. Sediment is the product of uncontrolled erosion. Everyone in Michigan is affected by erosion and off-site sedimentation. Erosion and sedimentation result in: loss of fertile topsoil, filling of lakes and streams, increased flooding, damage to plant and animal life, and structural damage to buildings and roads.”

“Construction is one of the major causes of erosion in Michigan. Without proper planning and management, over 100 tons of sediment per acre per year can be generated on some construction sites." 

After heavy or prolonged rainfall, silt runs off of ground that has been disturbed, i.e. loosened or dug up, as occurs at construction sites.  The regulation of silt runoff in Michigan leaves a lot to be desired.

The silt runs into lakes and streams or into combined (stormwater and human waste) sewer systems which lead to wastewater treatment facilities.  Silt causes turbidity in natural bodies of water, clogs sewers and imposes an added burden in treatment processes.  

During the heaviest rains, when the deluge threatens to overwhelm treatment plants, untreated or partially treated wastewater, laden by degrees with toxins, pathogens and sediment, is diverted into lakes and streams.  In our region, that means the Detroit River and Lake Erie.

For decades, water quality agencies in the region have been unable to manage such combined sewer overflows, which occur in the billions of gallons each year.  

Earlier schemes (e.g., immense storage tunnels) having been determined too expensive, new methods of controlling polluted overflows (principally, a number of relatively small retention-treatment basins) have been devised in the past two or three years and are being implemented.

Citizens, taxpayers and water services ratepayers would be well advised to learn about the new plans and watch to see how well they work.