Tag Archives: Kalamazoo River

U.S. Government Just Approved an Enormous Oil Pipeline

Repost from Mother Jones

The Government Quietly Just Approved This Enormous Oil Pipeline

Four reasons why people are outraged.

By Alexander Sammon, Aug. 12, 2016 6:00 AM
ewg3D/Thinkstock

It took seven years of protests, sit-ins, letter writing, and, finally, a presidential review to prevent the Keystone XL oil pipeline from being built. Now, in a matter of months, America’s newest mega-pipeline—the Dakota Access Pipeline Project (DAPL)—has quietly received full regulatory permission to begin construction. Known also as the Bakken Pipeline, the project is slated to run 1,172 miles of 30-inch diameter pipe from North Dakota’s northwest Bakken region down to a market hub outside Patoka, Illinois, where it will join extant pipelines and travel onward to refineries and markets in the Gulf and on the East Coast. If that description gives you déjà vu, it should: The Bakken Pipeline is only seven miles shorter than Keystone’s proposed length.

The proposed route of the recently approved Bakken Pipeline – Dakota Access

The $3.78 billion project is being built by Dakota Access, LLC, a unit of the Texas-based Energy Transfer Partners. (Former Texas Gov. Rick Perrya friend of Iowa Gov. Terry Branstad, sits on ETP’s board.) According to the firm, the Bakken Pipeline will transport up to 570,000 barrels of crude oil per day. Advocates have celebrated the supposed 12,000 jobs the pipeline will create in construction, while repeating calls to end American dependence on foreign oil—a platform called into question by new laws allowing US producers to export crude. The US Army Corps of Engineers gave its blessing at the end of July, clearing the final hurdle for the massive infrastructure project, which is slated to be operational by the fourth quarter of 2016.

Though the project hasn’t gotten too much national media attention, there’s been plenty of local opposition. Groups like the Bakken Pipeline Resistance Coalition, a collective of 30-plus environmentalists’ and landowners’ associations, along with Native American groups, have cried foul. Here are the four things they’re most outraged by:

How many jobs…really: According to Dakota Access’s DAPL fact sheet, the pipeline will create 8,000 to 12,000 construction jobs. An earlier draft of those figures claimed 7,263 “job-years” to be created in Iowa alone. Not so fast, says professor David Swenson, associate scientist in the Department of Economics at Iowa State University. Swenson crunched the numbers himself and came to a much more modest conclusion: 1,500 jobs total per year in Iowa for the course of construction. And given that most of these jobs are skilled, Swenson expects many of the hires will be from out of state, as Iowan contractors specializing in large-scale underground pipe-fitting and welding are scarce. The long-term forecast for job creation is even bleaker. The Des Moines Register reports that there will only be 12 to 15 permanent employees once the pipeline is completed. (DAPL has since walked back its job estimate slightly.)

Spill, baby, spill: As Sierra Club’s Michael Brune puts it, “It’s not a question if a pipeline will malfunction, but rather a question of when.” And, though they spill less often than trains do, the International Energy Agency found that pipelines spill much more in terms of volume—three times as much between 2004 and 2012. The Bakken Pipeline’s route takes it through active farmland, forests, and across the heartland’s major rivers: The Big Sioux, the Missouri, and the Mississippi, some with multiple crossings, though the US Fish and Wildlife Service claims that no “critical habitat” is endangered. It also runs through sacred Native American lands (more on this below).

Enbridge Inc., a stakeholder in the Bakken pipeline, has a speckled track record on spills. In 2010, an Enbridge pipeline spilled 1.2 million gallons of crude into the Kalamazoo River, one of the worst inland spills in American history. Because the pipeline qualifies as a utility (despite being privately owned and for-profit), the Army Corps of Engineers was able to certify it without performing an environmental impact statement, as all utilities projects qualify as “minimal impact.” These projects are subject to environmental assessments every five years.

Don’t tread on me: Private property owners, particularly in Iowa, have bristled at the Bakken Pipeline’s expropriation of land. ETP asked the Iowa Utilities Board to grant it the powers of eminent domain, the process by which a government can repossess private property for public use even if the private property owner does not voluntarily sell. The IUB, a three-person committee appointed by Republican Gov. Terry Branstad, granted ETP that right for its for-profit private pipeline, a practice that is not uncommon, in order to purchase 475 parcels from resistant landowners. This has led to numerous pending lawsuits, with the Des Moines Register reporting that the issue may make it all the way to the Iowa Supreme Court. In May 2015, ETP was embroiled in scandal after a contracted land agent, working on behalf of the Bakken Pipeline, allegedly offered an Iowan landowner a teenage prostitute in exchange for voluntary access to his property. (No charges were brought after the Iowa Department of Criminal Investigation determined that the case did not meet the legal standard for pimping, solicitation, or conspiracy.)

DisRezpect: The pipeline will cross through sacred lands and pass under the Missouri River twice. For the Standing Rock Sioux, the Missouri provides drinking water and irrigation, while its riverbanks grow innumerable plants of cultural import, including sage and buffalo berries. The tribe launched a campaign called “Rezpect Our Water” and staged a 500-mile relay race in protest, hoping to sway the Army Corps of Engineers in the permitting process. Last weekend, a group of 30 Native youth completed a three-week run from North Dakota to Washington, DC, where they delivered a petition of 160,000 signatures opposing the pipeline’s construction.

Now, even though the Corps has given the go-ahead, the tribe has not given up the fight. They recently filed suit against the Corps in federal court. The suit seeks an injunction, asserting that the pipeline will “damage and destroy sites of great historic, religious, and cultural significance,” a violation of the National Historic Preservation Act.

Though the pipeline seems to be a done deal, resistance of all types continues. Last week, the Des Moines Register reported that authorities are investigating suspected arson against the ETP’s heavy machinery. The fires, three separate incidents across two Iowa counties, resulted in nearly $1 million in damage to bulldozers and backhoes. The acts appeared to be intentional incidents of monkeywrenching.

On Thursday, a group of protesters, including the Standing Rock Sioux and their allies, gathered in North Dakota to oppose the pipeline, blocking the construction site. The police ultimately broke up the demonstration, resulting in at least five arrests.

No Dakota Access pipeline from Camp of the Sacred Stones blockade @POTUS@FLOTUS@USACEHQ
2:03 PM – 11 Aug 2016

Valero Crude By Rail: All about extreme crude (Canadian Tar Sands diluted bitumen)

Repost from the Sunflower Alliance

Valero Crude By Rail: Extreme Crude as Extreme Threat

By Charles Davidson, Hercules CA, February 20, 2016
CBR_3.jpg
Lynne Nittler of Davis, CA

Like many other fossil fuel infrastructure expansions in the Bay Area, the Valero Crude by Rail project is a key part of the transition to greater processing of extreme crudes. Yet another project poses significant, yet unnecessary public health hazards—this time to Benicia, the Bay Area, the Delta ecosystem and all communities up-rail from Benicia.

Valero’s recently completed Valero Improvement Project, or VIP, was designed to facilitate the processing of much higher sulfur and heavier crudes than the refinery’s former crude oil slate. The VIP permitted the Refinery to process heavier, high sulfur feedstocks as 60% of total supply, up from only 30% prior to the VIP.  The project also raised the average sulfur content of the imported raw materials from past levels of about 1 – 1.5% up to new levels of about 2 – 2.5% sulfur.

Now, Valero’s proposed Crude by Rail Project is specifically designed for the importation into Valero of so-called “mid-continent, North American” crudes, which would be either very lightweight, highly flammable shale oil from Bakken ND or extra heavy tar sands from Alberta Canada.  However, because the Valero Crude by Rail Project combined with the VIP are related parts of a single expanded heavy oil project, the Crude by Rail Project is most likely for the delivery of tar sands (bitumen).

Tar sands is open pit mined as a solid; it does not start out as a liquid. The Bitumen mined in Northern Canada needs to be heated to several hundred degrees before it can be diluted with chemical solvents and made to flow into railroad tank cars. According to the recent Carnegie Endowment study, Know Your Oil: Towards a Global Climate-Oil Index, tar sands refining produces three times the climate-changing greenhouse gases in order to make gasoline, compared to traditional lighter crudes.

Worse, in a 2007 US Geological Service study, it was reported that tar sands bitumen contains 102 times more copper, 21 times more vanadium, 11 times more sulfur, six times more nitrogen, 11 times more nickel, and 5 times more lead than conventional heavy crude oil. Sulfur and nitrogen oxide pollutants contribute to smog, soot, acid rain and odors that affect nearby residents. Because of these considerations, Benicia could likely experience an increase in local air pollution, and the refinery’s equipment could suffer enhanced sulfur corrosion, leading to potential accidents, such as documented for the 2012 Richmond Chevron fire.

The tar sand diluent itself adds significant risk: it is a highly flammable solvent that tends to separate from the heavier mixture during travel.  In a derailment this could cause an explosive fire with a uniquely hazardous tar sands smoke plume. The diluted tar sands mixture would tend to rapidly sink very deep into the soil, with the diluent eventually evaporating and then leaving the tar sands bitumen deep underground.

A significant tar sands spill, in places like the environmentally sensitive Feather River Canyon, the Delta or the Suisun Marsh would be impossible to clean up.  This was proven in Michigan’s 2010 Kalamazoo River Enbridge pipeline rupture, which will never be remediated, despite the spending of over 1 billion dollars to date. Nearby public infrastructure needs to be considered from a public health perspective; for example, East Bay MUD and others are doing a brackish delta water desalination pilot study near Pittsburg.

We must deny Valero the CBR permit and help keep the world’s absolutely dirtiest oil in the ground. To do so would comply with the expressed wishes of the Sacramento Area Council of Governments composed of six counties and 22 municipalities up-rail from Valero who have also asked that this project be denied. Our massive turnout at the Planning Commission hearings achieved our first step in this goal with a unanimous vote of the Planning Commission to deny the land use permit.  Now we must continue our opposition to insure the full Benicia City Council follows this path.

U.S. Not Prepared for Tar Sands Oil Spills, National Study Finds

Repost from Circle of Blue

U.S. Not Prepared for Tar Sands Oil Spills, National Study Finds

By Codi Kozacek, Circle of Blue, 10 December, 2015 16:07

Report urges new regulations, research, and technology to respond to spills of diluted bitumen.

China Shenzhen economic development office park economy Guangdong Province
Oil gathers in a sheen near the banks of the Kalamazoo River more than a week after a spill of crude oil, including tar sands oil, from Enbridge Inc.’s Line 6B pipeline in 2010. It was the largest inland oil spill in U.S. history. Click image to enlarge. Photo courtesy Sam LaSusa

Spills of heavy crude oil from western Canada’s tar sands are more difficult to clean up than other types of conventional oil, particularly if the spill occurs in water, a new study by a high-level committee of experts found. Moreover, current regulations governing emergency response plans for oil spills in the United States are inadequate to address spills of tar sands oil.

The study by the U.S. National Academies of Sciences, Engineering, and Medicine confirmed what scientists, emergency responders, and conservationists knew anecdotally from a major oil spill that contaminated Michigan’s Kalamazoo River in 2010 and another spill in Mayflower, Arkansas in 2013. Tar sands crude, called diluted bitumen, becomes denser and stickier than other types of oil after it spills from a pipeline, sinking to the bottom of rivers, lakes, and estuaries and coating vegetation instead of floating on top of the water.


“[Diluted bitumen] weathers to a denser material, and it’s stickier, and that’s a problem. It’s a distinct problem that makes it different from other crude.”

–Diane McKnight, Chair 
Committee on the Effects of Diluted Bitumen on the Environment


“The long-term risk associated with the weathered bitumen is the potential for that [oil] becoming submerged and sinking into water bodies where it gets into the sediments,” Diane McKnight, chair of the committee that produced the study and a professor of engineering at the University of Colorado Boulder, told Circle of Blue. “And then those sediments can become resuspended and move further downstream and have consequences not only at the ecosystem level but also in terms of water supply.”
“It weathers to a denser material, and it’s stickier, and that’s a problem. It’s a distinct problem that makes it different from other crude.” McKnight added. Weathering is what happens after oil is spilled and exposed to sunlight, water, and other elements. In order to flow through pipelines, tar sands crude oil is mixed with lighter oils, which evaporate during the weathering process. In a matter of days, what is left of the diluted bitumen can sink.

The study’s findings come amid an expansion in unconventional fuels development and transport in North America. Over the past decade, Canada became the world’s fifth largest crude oil producer by developing the Alberta tar sands. U.S. imports of Canadian crude, much of it from tar sands, increased 58 percent over the past decade, according to the U.S. Energy Information Administration.

Though oil prices are at a seven-year low, and market turbulence is expected to persist for several more years, tar sands developers are working to double the current tar sands oil production — around 2.2 million barrels per day — by 2030. Pipelines to transport all of the new oil are expanding too, producing a greater risk of spills.

China Shenzhen economic development office park economy Guangdong Province
A sign held by a protester at a 2013 climate rally in Washington, D.C. notes the lingering difficulties associated with spills of diluted bitumen –namely that the oil can become submerged in the water. Click image to enlarge. Photo courtesy DCErica via Flickr Creative Commons

Whether tar sands producers achieve that level of oil supply is not assured. Public pressure is mounting in Canada and the United States to rein in tar sands development due to considerable environmental damage and heavy carbon emissions. U.S. President Barack Obama last month scrapped the Keystone XL pipeline, an 800,000-barrel-per-day project to move crude oil from Canada’s tar sands to Gulf of Mexico refineries. An international movement to divest from fossil fuels and a legally binding global deal to cut carbon emissions –if it is signed in Paris– could curb demand for tar sands oil.

The National Academies of Sciences, Engineering, and Medicine study adds new data to arguments made by critics of tar sands development.

“The study really confirms a lot of the information that has been out there, there are no real surprises,” Jim Murphy, senior counsel for the National Wildlife Federation, told Circle of Blue. “You don’t want these things to be affirmed because it’s bad news for communities. But the good part about a study like this is hopefully it will prompt some action. Some folks were hiding behind the lack of a study like this, saying we don’t really know. Those excuses have gone away.”

“The chief takeaway is that this is a different oil, it presents different challenges, and responders and regulators simply don’t have the structures in place to deal with the challenges,” he added.

Nonetheless, energy companies are pursuing pipeline expansions, most notably in the Midwest and Great Lakes regions. Enbridge, Canada’s largest transporter of crude oil, operates a 3,000-kilometer (1,900-mile) pipeline network, known as the Lakehead System, that carries crude oil from Canada to refineries on the Great Lakes. The Lakehead system, in concert with Enbridge’s Canadian main line, is capable of transporting 2.62 million barrels of oil per day. The pipeline responsible for the 2010 oil spill in Kalamazoo was part of the Lakehead system. A link in the Lakehead system ruptured in 2010 and spilled more than 3 million liters (843,000 gallons) of tar sands oil into southern Michigan’s Kalamazoo River. It was the largest inland oil spill in U.S. history and its effects still linger because of oil that sank and is embedded in the river’s sediments.

 
“The chief takeaway is that this is a different oil, it presents different challenges, and responders and regulators simply don’t have the structures in place to deal with the challenges.”

–Jim Murphy, Senior Counsel
National Wildlife Federation


Enbridge is currently pursuing upgrades to its Alberta Clipper pipeline, which runs through Minnesota and Wisconsin, in order to boost the line’s capacity to 800,000 barrels per day from 450,000 barrels per day. A second project aims to increase the capacity of Line 61, a pipeline that runs from Wisconsin to Illinois, from 560,000 barrels per day to 1.2 million barrels per day. Opposition to the company’s operation of a pipeline that runs beneath the Straits of Mackinac, where Lake Michigan and Lake Huron join, has been especially fierce, though the line does not currently carry tar sands oil.

“I think at the very least we should be saying no to more tar sands through the [Great Lakes] region until we get a firm handle on how to deal with the unique challenges that tar sands spills present,” Murphy said. “We should also be taking a hard look, as the president did with the Keystone XL decision, about the other negative impacts of more tar sands oil, like the consequences in Alberta with the habitat destruction there, and also the higher carbon pollution content of the fuel.”

The National Academies study concluded that the characteristics of diluted bitumen are “highly problematic for spill response because 1) there are few effective techniques for detection, containment, and recovery of oil that is submerged in the water column, and 2) available techniques for responding to oil that has sunken to the bottom have variable effectiveness depending on the spill conditions.”

“Broadly, regulations and agency practices do not take the unique properties of diluted bitumen into account, nor do they encourage effective planning for spills of diluted bitumen,” it continued.

China Shenzhen economic development office park economy Guangdong Province
A tar ball recovered on the edge of a cove in Mayflower, Arkansas, after tar sands crude spilled from ExxonMobil’s Pegasus pipeline in 2013. Click image to enlarge.

The study’s authors made a series of recommendations to help reduce the damage from future tar sands spills, including:

  • Update regulations that would require pipeline operators to identify and provide safety sheets for each crude oil transported by the pipeline, catalogue the areas and water bodies that would be most sensitive to a diluted bitumen spill, describe how they would detect and recover sunken oil, provide samples and information about the type of oil spilled to emergency officials, and publicly report the annual volumes and types of crude oil that pass through each pipeline.
  • Require the Pipeline and Hazardous Materials Safety Administration (PHMSA), the federal agency that regulates pipelines in the United States, to review spill response plans in coordination with the U.S. Environmental Protection Agency and U.S. Coast Guard to determine if the plans are capable of responding to diluted bitumen spills.
  • Develop methods to detect, contain, and recover oil that sinks to the bottom of water bodies.
  • Require government agencies at the federal, state, and local level to use industry-standard names for crude oils when planning spill responses.
  • Revise oil classifications used by the U.S. Coast Guard to indicate that diluted bitumen can sink in water.
  • Collect data to improve modeling of diluted bitumen oil spills.
    Improve coordination between federal agencies and state and local governments when planning and practicing oil spill response exercises.
  • Develop a standard method for determining the adhesion –a measure of how sticky the oil is–of diluted bitumen in the event of a spill.

After the study’s release, PHMSA said it would develop a bulletin advising pipeline operators about the recommendations and urge voluntary improvements to their spill response plans. The agency also plans to hold a workshop next spring to hear public input on how to implement the recommendations, coordinate with other federal organizations to “advance the recommendations”, and work with industry representatives to improve spill response planning.

“We appreciate the work the National Academy of Sciences has done over the last few years in analyzing the risks of transporting diluted bitumen, including its effects on transmission pipelines, the environment and oil spill response activities,” Artealia Gilliard, PHMSA spokesperson and director for governmental, international and public affairs, said in a statement. “All pipelines transporting crude oil or any other hazardous liquid are required to meet strict federal safety regulations that work to prevent pipeline failures and to mitigate the consequences of pipeline failures when they occur.”


Codi Yeager-Kozacek is a news correspondent for Circle of Blue based out of Hawaii. She co-writes The Stream, Circle of Blue’s daily digest of international water news trends. Her interests include food security, ecology and the Great Lakes.

Kalamazoo River 5 years later – still cleaning it up

Repost from OnEarth Magazine, Natural Resources Defense Council
[Editor:  Significant quote: “The Kalamazoo River still isn’t clean.  Let’s not forget how much it cost to (not completely) clean the Kalamazoo. The current price tag is $1.21 billion (and rising), making it the most expensive onshore oil spill in U.S. history.”  – RS]

Remember the Kalamazoo

Five years ago, a pipeline spilled a million gallons of tar sands crude into a Michigan river—and we’re still cleaning it up.
By Brian Palmer, July 22, 2015
Skimmers, like these used to clean up the Deepwater Horizon spill, were useless in Kalamazoo, where the tar sands crude sank to the bottom. Photo: NOAA

Five years ago, in the middle of the night, an oil pipeline operated by Enbridge ruptured outside of Marshall, Michigan. It took more than 17 hours before the Canadian company finally cut off the flow, but by then, more than a million gallons of tar sands crude had oozed into Talmadge Creek. The oil quickly flowed into the Kalamazoo River, forcing dozens of families to evacuate their homes. Oil spills of that magnitude are always disastrous, but the Kalamazoo event was historically damaging.

The first challenge was the composition of the oil. Fresh tar sands crude looks more like dirt than conventional crude—it’s far too thick to travel through a pipeline.

Try pumping this through a pipeline. Photo: Suncor

To get this crumbly mess to flow, producers thin it out with the liquid constituents of natural gas. Diluted bitumen, or dilbit, as it’s called in the tar sands industry, is approximately three parts tar sands crude, one part natural gas liquids.

When dilbit gushed into Talmadge Creek in 2010, the mixture broke apart. The volatile natural gas liquids vaporized and wafted into the surrounding neighborhoods. The airborne chemicals were so difficult to find and eliminate that Enbridge decided it would be better to simply buy some of the homes that were evacuated, preventing the residents from ever returning.

The tar sands oil, which stayed in the water, presented an even bigger chemistry problem. Most forms of oil, including conventional crude, are less dense than water. That’s why oil makes such pretty colors when dropped into a rain puddle—it floats and plays tricks with the sunlight. Traditional oil spill cleanup technology relies heavily on this density relationship. Skimmers and vacuums remove it from the surface. Floating booms prevent surface-level oil from moving into environmentally sensitive areas.

Tar sands crude behaves differently. “Tar sands bitumen is a low-grade, heavy substance,” says Anthony Swift, director of NRDC’s Canada Project (disclosure). “Unlike conventional crude, when bitumen is released into a water body, it sinks.” (See “Sink or Skim,” onEarth’s infographic on why tar sands oil is more difficult to clean up than conventional crude.)

Skimmers, like these used to clean up the Deepwater Horizon spill, were useless in Kalamazoo, where the tar sands crude sank to the bottom. Photo: NOAA

Put simply, the spilled dilbit traveled in every direction—into the air, with the current, to the bottom of the river—at the same time. The U.S. Environmental Protection Agency’s indisputably naïve response reveals how little anyone knew about tar sands crude. The EPA demanded that Enbridge remove the oil from wetlands surrounding the pipe by August 27, a little more than one month after the spill began. The agency wanted the stuff out of the creek, river, and shorelines by the September 27. Those deadlines would have been practical for a typical spill—but not for a tar sands oil spill. A half-decade later, some of the oil still remains—though, much of that has to do with Enbridge botching the cleanup effort (see onEarth’s three-part series, “The Whistleblower”).

Enbridge’s bungling began even before the spill. First, the company knew the pipeline was vulnerable by 2005, if not earlier. When the rupture finally came in July 2010, operators dismissed the alarms as a malfunction of the system for 17 hours before finally accepting that the pipeline had failed. Making things worse, six hours after Calhoun County residents were complaining to 911 about the smell of oil, Enbridge employees were still trying to fix the problem by pumping additional oil into the pipeline. In its review of the accident, the National Transportation Safety Board faulted Enbridge’s “culture of deviance” for what happened, pointing out that the response team in the first hours consisted of four local pipeline maintenance employees who were inadequately trained and made a series of bad decisions.

Not only did Enbridge fail to make the EPA’s initial cleanup deadline, it also blew through a series of fallback deadlines across more than four years. Not until late 2014 did the agency finally sign off on the remediation effort, handing the remaining responsibilities to the Michigan Department of Environmental Quality.

As the cleanup winds down, though, there is little cause for celebration. “The Kalamazoo River still isn’t clean,” says Swift. “The EPA reached a point where additional cleanup might do more harm than good. Much of the river is still contaminated.”

Some local residents accuse the company of overstating its progress. “In the process of beautifying everything and giving money to everybody and making everybody feel good about it, they’re not really telling people about the dangers still there in that water,” says Linda L. Cypret-Kilbourne of Michigan’s Potawatomi tribe.

It’s not clear when the river will go back to pre-spill quality. After conventional oil spills, crews eventually back off and allow microbes to break down the last bits of crude. That approach isn’t a good option in Kalamazoo. First, the area doesn’t have a large natural population of oil-eating microbes like the Gulf of Mexico has. In addition, tar sands crude contains very high levels of heavy metals, which don’t break down easily.

Let’s not forget how much it cost to (not completely) clean the Kalamazoo. The current price tag is $1.21 billion (and rising), making it the most expensive onshore oil spill in U.S. history.

The Kalamazoo River still isn’t clean. The EPA reached a point where additional cleanup might do more harm than good. Much of the river is still contaminated.

It’s tempting to dismiss the slow, botched, expensive, and still-unfinished cleanup as growing pains. Tar sands imports have risen significantly since 2010, as has public awareness of the difference between the Canadian crude and the conventional product. In the five years since the incident, we should have improved tar sands oil spill response. But we didn’t.

If another Enbridge spill were to happen tomorrow, the company might respond more quickly, but huge volumes of heavy tar sands crude would still pour out of the pipeline. David Holtz of the Michigan chapter of the Sierra Club told reporters that a rupture in Enbridge Line 5, another pipeline that runs through Michigan, would be disastrous.

“If they hit the shutoff valve immediately after a rupture, there would still be more than 650,000 gallons of oil spilled into the Great Lakes,” he said.

Cleaning it up would be as challenging today as it was five years ago. There have been no technological breakthroughs since 2010. The tar sands industry should accept a large portion of the blame for this stasis.

“The efforts to improve spill response have been caught up in a public relations war,” says Swift. “The tar sands industry wants you to believe that oil is oil, and that its product involves no heightened concerns. As a result, spill responders are working with largely the same tools today as in 2010.”

Tar sands pipelines—like the one operated by Enbridge, or TransCanada’s proposed Keystone XL pipeline—run for thousands of miles, crisscrossing the United States and Canada in elaborate networks. They entail certain risks, and those risks are not going away. We have to decide how to respond. If we accept them, we must work to minimize the consequences by developing the appropriate safety measures and technology. Or we can reject them by eliminating tar sands from our energy infrastructure. The one thing we must not do is to pretend they don’t exist. The Kalamazoo spill is a reminder. It won’t be the last.