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The Bay-Delta Conservation Plan in A Nutshell

By: Jessie Quinn, Ph.D.

The deadline for the public review and comment period for the Draft Bay-Delta Conservation Plan is approaching in mere weeks, on June 13, 2014. Did you wait until the last minute to skim the approximately 40,000-page document and send in a comment or two? Fear not! Here in the Sacramento office of Great Ecology, we have a ringside seat for the development and (potentially) implementation of a plan that addresses one of the largest—if not the largest—water management challenges in California since the building of the California Aqueduct. In the interest of promoting an informed and involved citizenry, we have distilled the entire Plan down to an easy-to-follow information fact sheet for your edification.

San Francisco Bay Delta Watershed. Map courtesy of the U.S. EPA.

San Francisco Bay Delta Watershed.
Map courtesy of the U.S. EPA.

What is the Bay-Delta?
The Bay-Delta is shorthand for the San Francisco Bay-Delta Estuary, an inland Delta in northern California and the largest estuary on the west coasts of both North and South America. The entire Bay-Delta watershed covers more than 75,000 square miles (so, most of northern California). Fed by the melting snowpack, streams and rivers of several mountain ranges, the waterways of the Bay-Delta course across the state into several large bays before emptying into the Pacific Ocean near San Francisco.

What is the Bay Delta Conservation Plan?
The Bay-Delta Conservation Plan, or BDCP, is a regional Natural Community Conservation Plan (NCCP) that covers the central delta of the watershed, an area of 872,000 acres. The goal of the plan is to protect the water supply the Delta provides to 25 million people and over 3 million acres of agricultural land in California, while also maintaining ecosystem health of the associated wetland, riparian, grassland, and forest habitats and the plant and animal species.

Images show the Delta’s extensive network of levees, weirs and canals which provides water to 25 million people and over 3 million acres of agricultural land in California.  Left photo courtesy of

Images show the Delta’s extensive network of levees, weirs and canals which provides water to 25 million people and over 3 million acres of agricultural land in California. Images courtesy of, Left: James Davidson, Right: Flickr.

Why is the BDCP needed?
The existing water supply transport system, which conveys Bay-Delta water as far south as San Diego, consists of an extensive network of levees, weirs and canals. These aging above-ground structures are vulnerable to damage from natural disasters, such as a storm surges or earthquakes, and could result in the flooding of adjacent communities of over 500,000 people and hundreds of thousands of acres of farmland. Sea level rise due to climate change will likely increase the scale and frequency of these catastrophic events.

The problem doesn’t stop there. Saltwater intrusion from the San Francisco Bay has always been a natural component of the Delta tidal ecosystem. However, the diversion of freshwater out of the Delta through massive intake pumps at its southern end changes the natural east-west flows through the Delta’s wetlands to north-south flows, causing a buildup of salinity in the waterways. The increasing salty water threatens to impact plant and animal species with low salinity tolerance, such as the Endangered Delta Smelt (Hypomesus transpacificus). This, as well as the levees’ contribution to the loss of floodplain habitat, natural channel margins, and tidal marsh, has resulted in a highly altered and degraded system.

Moreover, the pumps themselves disrupt the passage and migration patterns of fish such as the Smelt, Steelhead, Chinook salmon, and sturgeon. To protect the fish, certain levels of water have been mandated to remain in the Delta by a 2007 court ruling.  This reduces the available water supply, particularly in drier years. This potential year-to-year fluctuation would impact the reliability of the supply delivered throughout the state, where the demand for water is certainly not diminishing.

What solution is the BDCP proposing?
The proposed solution: divert water from north of the Delta, higher up the Sacramento River through 2 massive underground tunnels, each of which is 40-feet wide and extends 35 miles south along the Sacramento river. These tunnels would divert freshwater to the Bay Area and southern California from further upstream before the water enters the Delta, thus ensuring a reliable, high quality water supply to most of the state, while also protecting the conveyed water from potential natural disasters. Additionally, the tunnels would allow the natural east west flows to return to the Delta estuary, allowing the restoration of natural fish movement patterns.

Proposed: Two 35-mile tunnels divert water north of the Delta to increase the water supply and protect valuable native ecosystems. Easy solution? Not quite…

So, problem solved, right?
Well, not exactly. The construction of tunnels will directly impact numerous habitats in the Bay-Delta region, and will also potentially create further saltwater intrusion and habitat degradation higher up the Sacramento River, since freshwater will be removed from higher reaches of the river. To address and compensate for these anticipated impacts, the BDCP includes a joint Environmental Impact Statement (EIS)/Environmental Impact Report (EIR) under the federal and state NEPA and CEQA processes. The plan and the EIS/EIR seek a 50-year project permit to proceed with the BDCP work, which would allow some take* of Threatened and Endangered species through the regulatory context of the Natural Community Conservation Plan (NCCP); as compensation for the take, the plan promotes landscape-level natural community conservation in an adaptive management framework. Thus the NCCP includes plans for approximately 150,000-acres of mitigation via habitat restoration throughout the Delta over the next 50 years to compensate for impacts to sensitive species and habitats from the tunnels’ construction

Wow, all that habitat restoration! So now the problem is solved, right?

Opponents of the Bay-Delta Conservation Plan.  Image courtesy of Censored News.

Not everyone is behind the Bay-Delta Conservation Plan.
Image courtesy of Censored News.

Not quite yet. Some argue that the plan does more harm than good, citing their worry about the increased salinity in the Sacramento River and in the Delta, which would compromise the water sources of the area’s farming operations. Yet another concern is that the tunnels will take too much water out of the rivers, drying up some downstream habitat in the drier years which are expected due to climate change and subsidence. In fact, the Delta Independent Science Board concluded that the Draft BDCP fell short of integrating the appropriate amount of science into the Plan. Particularly, the Board was concerned that the feasibility and effectiveness of the planned habitat restoration was overstated; that the plan lacked an adequate analysis of uncertainty; that there was an exclusion of discussion about climate change effects on the project over time; and that the detail in describing adaptive management methods was insufficient. This analysis was released in a report last week. Not to mention, it’s expensive: the official price tag is $25 billion, but critics claim that the actual costs could be as high as $67 billion when interest and other costs are included.

What if they fix the restoration plan and then it gets approved?
There would be yet another hurdle for the BDCP to overcome. Assuming that no lawsuits delay the EIS/EIR approval or project implementation, the funding for the habitat restoration is not guaranteed. The $4.4 billion required for the full habitat restoration will be supplemented by several sources; some of that funding depends on the passage of two Water Bonds that require passage by the voters of California. The first Water Bond has been working its way through the legislative process since 2009 and is planned for submission to the voters this year.

Now what do I do? I want to learn more about this BDCP.
Well, the BDCP website breaks down the 40,000 page behemoth into its pertinent parts to make it more digestible for the public. If you want to search farther afield and simply do a Google search for “BDCP,” you’ll be hard-pressed to find a site that doesn’t offer some strong opinion on the Plan. With a critical eye, read these pages, too! Taking the time to learn about these multiple perspectives is first step into the world of science, land management, economics, and politics that we practitioners often live in… and it’s not always pretty.

Even if you don’t plan on commenting on the Draft BDCP, the site—and the sites that have something to say about it—contain a wealth of information about the ecology of a magnificent and imperiled ecosystem. The BDCP also provides a valuable opportunity to learn about the fascinating, complex story of the long history and uncertain future of water management in California.

*The Endangered Species Act defines “take” as to “harass, harm, pursue, hunt, shoot, would, kill, trap, capture, or collect.”

 

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Urban Habitat Restoration Gaining Ground

President Dr. Mark Laska is featured in the recent Sustainable City Network’s article, Habitat Restoration Projects Abound in Urban SettingsDr. Laska joins a panel discussing the growing focus and momentum of urban habitat restoration projects within the last 10-15 years and how this trend will continue to define our future cities.

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Retrofitting the North Atlantic Coast

By: Charlie Howe

There’s no catchall solution for sea-level rise retrofitting.

Last month the U.S. Department of Housing and Urban Development’s (HUD’s) Hurricane Sandy Rebuild Task Force unveiled 10 storm-protection proposals for the north Atlantic coastline. The proposals, which are the culmination of 10 months of research and conversation by some of the most accomplished thinkers in urban design, form the third phase of the HUD’s Rebuild by Design competition, a high-profile ideas contest aimed at developing “regionally-scalable but locally contextual” pilot projects to increase coastal resiliency.

The contest generated new conversations about what post-Sandy resiliency looks like and when the Rebuild by Design jury selects a winner (or winning projects) they will set a course for future storm-proofing efforts along the North Atlantic.

The Rebuild by Design jury is currently evaluating which proposed designs will be constructed using HUD disaster recovery grants. Considering the attention on the contest and the potential impacts of any of the proposed projects, selecting a final project is a difficult task. The jury must compare proposals that provide a suite of benefits beyond just flood protection.

Design teams are all multidisciplinary and draw on a wide range of skills and incorporate diverse values. Proposals that begin with flood prevention also layer in pedestrian circulation, waterfront access, educational opportunities within the natural environment, and nearshore habitat improvements. As former commander of the New York District of the U.S. Army Corps of Engineers, John Boule describes Rebuild by Design ‘…is revolutionary in the sense that we’re looking at environmental benefits, we’re looking at ecosystem services, the social value of projects. We’re incorporating those metrics. Deciding how to bring those metrics into the cost benefit analysis is a huge challenge and has tremendous potential to change federal policy, national policy.’

One finalist, the SCAPE Living Breakwaters proposal creates shellfish habitat in a series of breakwaters that would reduce storm surge on the southern coast of Staten Island, an area with some of the highest surge during Hurricane Sandy. The proposal explains that increasing function of nearshore habitat would not only provide benefits to local fisheries, but could create a focus for secondary education in environmental science.

Rendering of a proposed water hub on the shorelines behind the Living Breakwaters providing a space for recreation and education. Rendering courtesy of the SCAPE team.

Rendering of a proposed water hub located on the shorelines behind the Living Breakwaters. The hubs provide a space for recreation and education. Rendering courtesy of the SCAPE team.

Beyond weighing the many secondary benefits of each proposal, the jury must also consider projects which address storm surge at drastically different scales. The smallest, neighborhood scale proposals provide a means of targeting investment in the most vulnerable or highest value areas of the city. Projects of this size may achieve the highest return on investment in terms of flood protection per dollar invested in infrastructure. This is the ‘bang for the buck’ approach most clearly adopted in OMA’s proposal for Hoboken. Of course, it’s important to remember the benefits of neighborhood scale projects are localized and these strategies cannot be implemented in every neighborhood. The most ambitious projects, would require substantially greater funds, perhaps even surpassing the total budget allocated for post-Sandy rebuilding, $50 billion. However, it would take an approach of this scale to extend flood protection across neighborhoods and boroughs, see WXY & West 8′s Blue Dunes.

The proposed Blue Dunes design creates an offshore barrier island chain centered on the New York Bight.

The proposed Blue Dunes design address storm surge at the large scale by creating an offshore barrier island chain centered on the New York Bight. Rendering courtesy of the WXY West 8 team.

It’s clear, when evaluating the Rebuild by Design’s final proposals, each with it’s own merit, that there’s no catchall solution for sea-level rise retrofitting. For this reason, the Metropolitan Waterfront Alliance has formed a multidisciplinary group to collaborate and create design guidelines for waterfront development. When complete, the Waterfront Edge Design Guidelines (WEDG) will provide a framework for incorporating the multi-functionality and resilience evident in the ten Rebuild By Design proposals in all new waterfront construction. It has been an exciting opportunity for Great Ecology to collaborate with other architects, environmental consultants, and environmental regulators to help define and protect our coastlines.

Retrofitting the north Atlantic coast will require a variety of flood protection measures, at various scales. Evaluating the cost-benefit of these projects requires us to consider environmental and social benefits in tandem with flood protection performance and has the potential to greatly enrich coastal communities.

 

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Join Us at the Mitigation Banking Conference

Great Ecology is excited to exhibit at the 2014 Mitigation Banking Conference in Denver – May 7-9.

Come meet our team of expert mitigation consultants including, President, Dr. Mark Laska, Senior Ecologists Dr. Puja Batra and William Coleman, and Ecologists George Patten and Joshua Eldridge. See you all in Denver at booth #17!

Learn more about our mitigation banking services, ranging from project strategy to long-term stewardship.

2014 Mitigation Banking Conference Booth

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The Everglades: Seen from the Tamiami Trail

By: Colleen Tuite

Strike out west from Miami on Route 41, historically known as the Tamiami Trail. Pass through the jungle of overpasses and freeways, which then smoothes into a sea of urban sprawl – strip malls and Best Buys. Keep moving. The sprawl ends, suddenly, and gives way to something even more ominous: a forest.

Melaleuca forestThese are Melaleuca and Australian Pine trees, planted extensively in the 20th century as a method to drain what was considered to be the unsightly and murky swamp we now call Everglades National Park.

Introduced from Australia in 1902 by the USDA, Melaleuca quinquenervia was considered a godsend: for the hand-wringing public officials of the 19th and early 20th century, convinced wetlands brought nothing but disease; for the U.S. military, charged with eradicating the indigenous Seminole people from their home; and for developers, looking to fabricate buildable and arable land. Deep roots pump up thousands of gallons of the so-called “miasmatic and malaria-filled” water which fuels the Everglades wetland system, effectively sucking it dry. By the 50s, it was understood that the rapid growth and ecosystem changes wrought by the Melaleuca may not bode well, but planting continued through the 70s, creating over 500,000 acres of water draining monoculture.

Forest of dead Melaleuca trees Continue your drive west, and eventually the forest opens to a grassland, punctuated by the skeletons of hundreds of dead Melaleuca trees. Now considered an invasive, Melaleuca is being controlled by quarantining, herbicides, and biological agents such as weevils. In the past 20 years the acreage covered by Melaleuca has been cut in half, with the intention of restoring native plants and habitat.

Press on and the landscape widens into a vast grassland. Canalization of the EvergladesNotice that you are now driving alongside a canal – and slowly realize that the road you are traveling on is bisecting the flow of surface water through the Taylor Slough drainage system and into the Glades, effectively choking the system of much needed freshwater recharge. Instead of replenishing freshwater in the wetlands to the south, this captured water is diverted to be used for irrigation. Between the 1950s and 60s, over 1400 miles of canals were constructed for both flood control and to capture water for use in cities and agriculture.

The canalization of the Glades has created the Everglades Agricultural Area – an artificial oasis of farms, nurseries and roadside markets just above the protected boundary of the National Park. The willful mismanagement of this area began in the 1920s, with the dumping of manganese sulfate into the then-wetland to encourage agriculture. Water trucksThe tradition continues today: while the Glades remain starved for freshwater, here one can observe fields being irrigated by trucks cheerfully spraying thousands of gallons of water into the air – a demonstration of what has to be the least efficient method of watering possible.

Agriculture is a major culprit for diminished water quality in the Glades. Not only does decreased freshwater increase salinity, but runoff water from the farms that does make it into the wetland is often loaded with fertilizers and petrochemicals. Legislation in the early 90s has helped control levels of phosphorous, but mercury levels remain a concern, especially as it bioaccumulates in larger (often already endangered) animals, such as panthers.

For the past 20 years, a program called the Central and South Florida Project Restudy has been operating to create a comprehensive recovery plan for the Everglades. However, it’s difficult to undo almost two centuries of mismanagement/ willful destruction, especially now that industries in the region depend on the denial of resources to the Glades. However, over 36,000 acres of artificial wetlands have been created to capture stormwater, filter phosphorous from runoff, and recharge the Everglades, including a 16,000-acre site which takes home the title as the largest constructed wetland in the world. More recently, some canals have been rebuilt in order to allow water to flow back where it belongs.

Looking ahead at the future of the Everglades, it’s clear that after centuries of mismanagement and neglect, this unique ecosystem will never return to its pre-1800s condition. But that’s ok – South Florida is now a rich mosaic of nature and culture that will remain linked. Opportunities exist to restore ecological functionality to the Everglades, while still allowing for human needs within the landscape, such as farming and recreation. Constructed wetlands are the first step in creating a shared ecosystem between agriculture and nature. The removal and reconstruction of canals and levees to restore water flow into the Glades need not be the end of fishing – these popular spots can be mitigated by introducing fishing into the constructed wetlands, and by creating artificial lakes which double as freshwater storage during seasonal flooding. By understanding and designing to meet these layered needs, an ecologically and culturally complex and resilient landscape is possible.

Mangroves

Mangroves and nesting pelicans in the Everglades

References:
Carter-Finn, Katherine, Alan W. Hodges, Donna J. Lee, and Michael T. Olexa. The History and Economics of Melaleuca Management in South Florida. EDIS New Publications RSS. University of Florida IFAS Extension.

Harvey, Rebecca G., William F. Loftus, Jennifer S. Rehage, and Frank J. Mazzott. Effects of Canals and Levees on Everglades Ecosystems: Circular. EDIS New Publications RSS. University of Florida IFAS Extension.


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Marine Ecosystems Battling Oil Impacts

By: Ashley Tuggle

The Gulf of Mexico is one of the most active areas for oil drilling in the country. According to the U.S. Energy Information Administration, the Gulf accounts for 23% of total crude oil production and the Gulf coast contains over 40% of the oil refining capacity in the country. That much production and refining capacity centered in one region has made the Gulf a prime area for oil-related injuries. Galveston Bay in Texas, alone, has had an average of 285 oil spills annually since 1998.

The March 22 Houston Channel oil spill dumped 170,000 gallons of oil into the ecosystem. Image courtesy of

The March 22 Houston Channel oil spill dumped 170,000 gallons of oil into the ecosystem. Image courtesy of National Geographic Staff.

Most recently, the Houston Ship Channel oil spill on March 22 disrupted not only the Gulf’s ecosystem, but one of the busiest seaports in the nation, gaining national attention for the magnitude of the spill, 170,000 gallons of tar-like oil, and its commercial and environmental impacts. The Channel closed for 4 days and significant injuries to marine and coastal wildlife were reported.

Under the Oil Pollution Act of 1990, responsible parties must provide compensation for these natural resource injuries on top of the fines related to the spill itself. While the full magnitude of the Channel spill’s impacts is still to be determined, it could be extensive as globally significant important shorebird habitat lining both sides of the waterway. The timing of the spill is especially concerning given that it comes just before peak shorebird migration season when tens of thousands of birds will pass through the area surrounding the Houston Ship Channel.

Compensation for environmental impacts from spills of this size typically comes from habitat restoration or creation. A tool called Habitat Equivalency Analysis can help translate environmental damages to wildlife and habitat into restoration acreage.

Spills from ships and pipelines are not the only culprits for oil impacts in North America’s coastal waters. Widely-publicized major spills like the Houston Ship Channel spill typically account for only 8% of the petroleum inputs into the North American marine ecosystem. Natural seeps, cars, and other land vehicles, along with recreational boats are major contributors to oil pollution in the Gulf. It is death by a thousand paper cuts. None of these impacts are on the scale of oil spills, but taken in sum, they can add up to the more insidious and chronic injuries impacting our oceans.

Natural oil seeps in the Gulf of Mexico. Image courtesy of the NASA Earth Observatory.

Oil on the surface of the Gulf of Mexico, from the natural seeps. Image courtesy of the NASA Earth Observatory.

Natural seeps contribute the majority of the oil load in North American waters, about 60%. However, bacteria have evolved around these seeps that naturally break down the oil coming from them, which is why it is much more of an issue when an oil spill from a tanker occurs in an area that doesn’t have these seeps or bacteria.

Cars and other vehicles constantly drip oil, further contributing to the problem. Many storm drains lead directly to the nearest water body without treating stormwater. This means that whatever happens to be on the street at the time may impact the nearby aquatic environment. This kind of pulse impact can lead to more chronic problems in the ecosystem as low-level influxes of oil occur continuously.

Recreational boating can result in small-scale spills that may go unnoticed or unreported. Some experts have noted that as many as 80% of small spills from recreational boats go unreported. This makes tracking the chronic impacts and the full magnitude of these types of spills complicated for regulators and researchers. In busy recreational areas, small spills may represent a much greater proportion of the impact from oil than large-scale spills since they occur on a more consistent basis. They may be the main source of oil for areas that have little to no commercial boat traffic or drilling activity.

Regardless of the source of oil, the impacts of spills, acute and chronic, on our marine ecosystems are extensive and an ongoing problem. When planning for restoration in compensation for major spills, the myriad sources of coastal pollution from oil and other sources must be taken into account for an effective habitat design that can withstand and sometimes even help to cleanse these environmental stressors from an ecosystem. Ending all oil spills is probably not possible, but designing restoration to try to combat their impacts is. Understanding the ecology of a system and the processes that make it more resistant and resilient to oil and other stressors can be the deciding factor in the success of a restoration project. With oil spills, large and small, and the other threats to our coastal waters, restoration success is something our marine ecosystems desperately need to survive.

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A river runs through it, again

By: George Patten

An extraordinary ecological restoration effort is currently happening in Mexico, and if the star-studded (and brilliant) public service announcement featuring Will Ferrell, Robert Redford, and Kelly Slater is any indication, recent efforts to revive a dried up portion of the Colorado River delta are, in the words of Ferrell’s character Ron Burgundy, “kind of a big deal”.

for the first time in decades this 70-mile stretch of the Colorado River will flood.  Map courtesy of Wikipedia.

For the first time in decades this 70-mile stretch of the Colorado River will flood. Map courtesy of Wikipedia.

The Colorado River is one of the most celebrated drainages in the West – forming out of the high Rockies and flowing over 1400-miles through places like the Grand Canyon. But few realize that the river runs dry before reaching its historic delta in the Gulf of California. The 70-mile stretch of river south of the U.S. border once flowed into a rich delta ecosystem, but as a result of numerous pressures on the river’s water supply the delta has become dry and barren.

For the first time in decades the river is coursing its way towards the Gulf thanks to a binational agreement between the U.S. and Mexico. The historic and unprecedented restoration event involves a one-time release or “pulse flow” into the lower reaches of the river in an effort to revive the former ecological conditions of the delta.

Colorado River running through the Grand Canyon. Photo courtesy of George Patten.

Colorado River running through the Grand Canyon. Photo: George Patten.

The Colorado River drains an enormous area in the western U.S. and traverses multiple states before crossing the border into Mexico. The expansive and mostly arid Colorado River watershed is highly influenced by annual snowpack in the northern portion of the basin. The River is also one of the most valued and managed water sources in the western US, with multiple dams and massive engineering projects and serves as a key source of water to multiple western states. Numerous compacts and regulations manage and allocate flows within the river between northern and southern basins, as well as between the U.S. and Mexico – collectively known as the Law of the River. Despite measures to help manage use of the river’s annual flows, increasing demand, impoundments, and periods of drought have contributed to the drying of the river prior to reaching the delta, which has in turn affected the natural ecology of the system.

Water released from the Moreles Dam on the first day of the pulse. Image courtesy of John Fleck.

Water released from the Morelos Dam on the first day of the pulse. Image courtesy of John Fleck.

The terms for the pulse flow were established as part of a binational agreement between the U.S. and Mexico, called Minute 319. The release of the pulse, which began on March 27 and will flood the region with over 100,000 acre-feet of water, mimicking high spring water flows that formerly occurred naturally in the basin.

Several groups are monitoring the status and impacts of the pulse flow, including the effects to ecosystems and wildlife in the Colorado River delta. The high pulse flow is designed to help support establishment of riparian vegetation and trees, such as cottonwoods and willows. Riparian birds and other wildlife are also likely to benefit from the flows through improved habitat and resource availability.

Although the event appears to be one-time, it sets the stage for future conservation efforts and marks a shift in conservation and resource management priorities for the Colorado River basin. According to the International Boundary and Water Commission, the pulse is part of a “broad package of cooperative measures for Colorado River water management by the United States and Mexico that protects both countries’ interests in this essential natural resource.”

 

References:

Bureau of Reclamation: Lower Colorado Region – Law of the River. Bureau of Reclamation: Lower Colorado Region – Law of the River. U.S. Department of the Intentior, Mar. 2008.
Colorado River Begins Flooding Mexican Delta. KPBS Public Broadcasting. Ed. Associated Press. N.p., 27 Mar. 2014. Web.
Commission Marks Historic Environmental Flow In The Colorado River. International Boundary and Water Commission United States and Mexico, 27 Mar. 2014. Web.
Postel, Sandra. Monitoring the Pulse of the Colorado River. News Watch. National Geographic, 5 Apr. 2014. Web.
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Understanding and Navigating the Proposed Clean Water Act Update

The U.S. Army Corps of Engineers and U.S. Environmental Protection Agency issued a proposed update to the Clean Water Act (CWA) on March 25, 2014. It seeks to clarify the definition and scope of Waters of the United States following the 2006 Rapanos v. United States ruling which narrowed the definition of Waters of the United States. The update addresses certain aquatic resources currently not under CWA jurisdiction, including isolated wetlands, riparian areas, and tributary streams that flow perennially or ephemerally, and provides increased consistency across regional and local agencies in the application of jurisdictional water determinations. If finalized after the 90 day comment period, the update will affect both Section 404 permitting and mitigation requirements significantly impacting future development projects

If passed, there are a lot of changes coming. Great Ecology is focused on staying up to date with the changes. Contact us with any questions regarding how the proposed changes may affect your projects and what you should do in the interim.

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Flooding in the UK Highlights the Need for Resilient Cities

By: Alicia Smith

Massive wave crashing into the sea wall at Ilfracombe, North Devon. Photo courtesy of Paul Grover/Telegraph.

Massive wave crashing into the sea wall at Ilfracombe, North Devon. Photo courtesy of Paul Grover/Telegraph.

This January was the wettest winter recorded in the UK in 250 years highlighting the need for increased storm and flood protection. Gales and tidal surges battered the coast, leaving whole villages under water, crumbling coastal cliffs, eroding beaches and sand dunes, and breaching river banks. The western and southern areas of the UK were the hardest hit and were still saturated after six weeks of heavy rainfall.

The severe weather forced the Environmental Agency to issue its first 2014 red weather warning in February, as strong winds were predicted to reach 100mph. The storms left tens of thousands of homes without power and caused flooding in the Thames Valley, breaking banks along a nearly 62 mile stretch from Oxford to Kingston, in Greater London.In addition, groundwater flooding has been an issue as a result of soil saturation.

By 2050 the frequency of severe flooding across Europe is expected to double, causing potentially a five-fold increase in annual economic losses due to flood damage. Climate change and increase in rainfall are expected to result in a third of the losses, while properties and infrastructure lying in flood prone areas account for the rest.

Given the recent storms, experts from 17 environmental and planning organizations including ecologists, landscape architects, engineers and hydrologists have asked the government to address flooding by creating a flood defense policy for the future. According to one environmental professional, “water management techniques could have helped prevent the effects of flooding on villages, towns and over surrounding land seen recently. Emergency measures are in order for the immediate crisis. But in the long term, the management of water requires a clear strategy.” This could include the use of forestry and land management to hold back the water in the uplands, as well as dredging in the lowlands.

While some protective measures are in place, there are concerns that they are not strong enough to protect against higher frequency and severity storms. The Thames Barrier was built after the flood of 1953, when a surge in the North Sea killed more than 300 people. Today, it still functions as a protective barrier for central London and protects more than 1 million people and £200bn in property values, including historic landmarks and the Underground.

Thames Barrier protects London during high tides. Can it withstand future higher frequency and severity storms? Image courtesy of Halcow.

Thames Barrier protects London during high tides. Can it withstand future higher frequency and severity storms? Image courtesy of Halcow.

Twice a day, the incoming tide from the North Sea rushes towards the ten 3,300 ton steel gates of the Barrier, where water levels can rise and fall by 30 feet. The Barrier prevented catastrophic damage during the December 2013 storm surge-the largest in 60 years,  however rising sea levels are a serious threat. A global study recently concluded there is a 1 in 20 risk that the existing Thames Barrier would not be able to withstand a severe storm event

Flooded London if  Thames Barrier did not exist.  Image courtesy of the Environmental Agency.

The potential effects on central London if there was no barrier during the December 2013 storm surge – the largest in 60 years.
Image courtesy of the Environmental Agency.

Large metropolitan cities, such as London and New York are still struggling to protect themselves from storm surges, severe flooding, and sea-level rise. Hard structures, such as sea walls are effective barriers, but have high costs and can cause have detrimental impacts to the environment. Over the past decade, government policy in the UK largely focused on the widening and dredging of riverbeds to allow the water to flow downstream, however, many are now suggesting other alternatives. Natural buffers, such as tidal marshes, coastal wetlands, barrier islands and other natural ecosystems can provide protection against sea-level rise. Other approaches,  including “rewilding” or planting trees in upland floodplains to hold back and slow down water has been proposed by leading scientists. Projects that work to create a dynamic interface between built and natural buffers are needed worldwide, requiring a multi-disciplinary approach with many organizations involved as well as the political leadership and will to create more resilient cities, coastlines, and agricultural areas.

 

References:
Carrington, Damian. January Was England’s Wettest Winter Month in Almost 250 Years. The Observer. Guardian News and Media, 02 Feb. 2014.
Connor, Steve. Frequency of Severe Flooding across Europe ‘to Double by 2050′. The Independent. Independent Digital News and Media, 2 Mar. 2014.
Flooding And Erosion Damage Across The UK. Sky News. N.p., 21 Feb. 2014.
Floods Crisis: Is London in Danger? Channel 4 News. Channel 4 News, 10 Feb. 2014.
Harrabin, Roger. Lord Rooker: ‘Planting Trees Could Stop Flooding’. BBC News. BBC News, 23 Jan. 2014.
Marsden, Sam, and Peter Dominiczak. David Cameron Must Lead Planning Revolution to Prevent Future Floods, Say Experts. The Telegraph. Telegraph Media Group, 30 Feb. 2014.
Siddique, Haroon, and Matthew Weaver. Red Weather Warnings Issued as 100mph Winds Head towards UK. Theguardian.com. Guardian News and Media, 12 Feb. 2014.
The Government Needs to Call in the Flood Experts. The Telegraph. Telegraph Media Group, 21 Feb. 2014. Web.
UK Storms: Mapping the Floods. BBC News. BBC News, 14 Feb. 2014. Web
UK Storms: Homes Left without Power and Travel Disrupted. BBC News. N.p., 13 Feb. 2014.

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Carbon Offset Credits: Tradable Market Goods

By: Marlene Tyner, M.E.S.M.

Exciting news in the fight against climate change and deforestation. In November 2013, the California Air Resources Board (ARB) issued its first set of carbon offset credits for a validated forest conservation project. The Willits Woods Project, located in northern California’s Mendocino County and developed by Coastal Ridges, LLC, generated 1.2 million offset credits based on the amount of carbon stored in its 19,000 acres of forestland. ARB also granted credits to another forest conservation project, located in Maine, which generated almost 250,000 carbon offset credits.1

What are offset credits and why are they important?

Carbon offset credits reflect how much carbon has been taken out of the atmosphere by a human action, rather than put in, allowing those reductions to become tradable market goods. Entities such as private landowners, non-profit organizations, and corporations, can generate carbon offset credits and then sell them to companies who are emitting too much carbon. Companies with high carbon emissions can buy offset credits to effectively “cancel out” some of their emissions.2

The cap and trade market established by California Assembly Bill (AB) 32 regulates over 400 large utility and manufacturing companies with facilities located within the state of California.3 California allows these companies to apply offset credits to 8% of their emissions cap and these offset credits can be generated by actions taken anywhere within the United States. Offset credits are therefore a powerful incentive for companies to conserve forests, either through direct action by generating their own offset credits, or indirectly by purchasing credits generated by an outside entity’s forest project. This is especially true since offset credits cost less than emitting credits (about $9 per offset credit versus $12 per carbon allowance).1,4 Based on these estimated costs, the Willits Woods project generates approximately $3.6 million in potential gross compliance cost savings.

What kind of projects can generate credits?

Forests are widely recognized for their ability to remove CO2 from the atmosphere. There are three general kinds of forest conservation projects that the ARB will recognize under the U.S. Forest Projects Compliance Offset Protocol:

  • Reforestation
  • Improved Forest Management
  • Avoided Conversion

Reforestation Projects significantly increase forest cover on non-optimal logging land that will not be commercially developed. Efforts to plant trees in historically forested areas that have either experienced 90% or more deforestation or have 10% or less of their original stand biomass remaining6.

Improved Forest Management Projects, such as the Willits Woods Project, increase the amount of sequestered carbon in forests based on recognized sustainable forest management practices. These practices include increasing the rotation time between harvests on timberland, logging fewer trees, or clearing out invasive species or underbrush to optimize the productivity of the forest7.

Avoided Conversion Projects are privately-held forested conservation easements that have demonstrably avoided a significant conversion threat.

The amount of carbon stored in a tree varies depending on the species and its physical characteristics (height, trunk diameter, root mass, etc), which impacts how much carbon is stored in the forest. The ARB therefore uses models and measurements to establish a baseline carbon amount for each forest project. This number acts as a legitimate and validated measure of how much carbon is stored in the forest. This is then used to determine the number of carbon credits issued for the project. Validating the amount of carbon stored in the forest project ensures that all credits traded on the market are standardized and also acts as a deterrent to carbon fraud. The forest project carbon stocks are measured and updated annually.8

While there are many other specific details regarding how forest projects are deemed eligible for offset credits, in general projects must be located in the United States (as opposed to the United Nations’ similar programs, REDD and REDD+, which are aimed at mitigating climate change through conserving tropical forests in developing countries), they must be voluntary, and they must have the quality of additionality. This means that the landowner must actively increase the amount of carbon sequestered in the forest, on a piece of land, relative to the amount the forest would sequester if it were not owned by the landowner. This requirement explains why all the project types involve increasing tree biomass on land either through tree planting or altered stand management techniques.

Producing carbon offset credits with conserved forestland represents a significant opportunity for companies to generate value for their shareholders while meeting their emissions cap requirement or helping to reduce emission penalty fees and creating environmental value. It also allows private landowners to generate revenue from their property while increasing the quality of forest on their land. The Forest Project Offset Protocol represents another way California’s carbon market is generating win-win opportunities for businesses, landowners, and other stakeholders while tackling one of the defining environmental challenges of our time.

Additional information:

References:

  1. “First California carbon offsets approved under Forestry Protocol: Press Release 13-71.” California Environmental Protection Agency Air Resources Board News Release. 2013. State of California.
  2. Samuel, Molly and Laurent Sommer. “Cap-And-Trade 101: How California’s Carbon Market Works.” QUEST: The Science of Sustainability. Science.KQED.org. 9 Nov. 2012.
  3. “Program Links: List of Covered Entities.” Allowance Allocation. California Environmental Protection Agency Air Resources Board, 1 Nov. 2013.
  4. Carroll, Rory. “California Issues First Carbon Offset Credits Via Forest Conservation Under Cap-And-Trade Program.” The Huffington Post. TheHuffingtonPost.com, 14 Nov. 2013.
  5. Nabuurs,  G.J.; Masera, O.; Andrasko, K.; Benitez-Ponce, P.; Boer, R. ; Dutschke, M.; Elsiddig, E.; Ford-Robertson,  J.;  Frumhoff, P. ; Karjalainen, T.; Krankina, O.; Kurz, W.A.; Matsumoto, M.; Oyhantcabal, W.; Ravindranath, N.H.; Sanz Sanchez, M.J.; Zhang, X.  2007: Forestry.  In Climate Change 2007: Mitigation. Contribution of Working Group III to the Fourth Assessment Report of the Intergovernmental Panel  on Climate Change [B. Metz, O.R. Davidson, P.R. Bosch, R. Dave, L.A. Meyer (eds)], Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA.
  6. Grover, Ellen. “Forest Owner Opportunities in California’s Cap and Trade Program.” Karnopp Petersen LLP. Karnopp Petersen LLP, 23 Jan. 2014.
  7. “Forest Carbon Offsets: Case Studies.” Ecotrust. Ecotrust, 2013.
  8. California. Environmental Protection Agency Air Resources Board. Compliance Offset Protocol: U.S. Forest Projects. October 20, 2011.
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