Monday, April 7, 2014

The WIPP problem, and what it means for defense nuclear waste disposal

The WIPP problem, and what it means for defense nuclear waste disposal

Robert Alvarez

“It’s a surprise when there are no surprises," a cleanup worker told me a few years ago at the Hanford site in Washington state, once the world’s largest producer of plutonium for nuclear weapons and now home to a massive effort to stop leaking nuclear waste tanks from poisoning the Columbia River. This maxim can hold painfully true for a variety of events assigned an extremely small chance of happening. On February 4, 2014, assumptions of very low probability crumbled at the Energy Department’s Waste Isolation Pilot Plant (WIPP) near Carlsbad, New Mexico, when a fire in a large salt truck raged for hours, deep underground.

Ten days later, an even more unlikely accident happened: Wastes containing plutonium blew through the WIPP ventilation system, traveling 2,150 feet to the surface, contaminating at least 17 workers, and spreading small amounts of radioactive material into the environment.

"Events like this simply should never occur. One event is far too many,” Ryan Flynn, New Mexico’s environment secretary, said immediately after the accident. The US Energy Department, which oversees WIPP, views the fire and leak as simply small bumps in the long road of running a long-term waste repository. “Without question, there is absolutely not an iota of doubt …. We will re-open,” David Klaus, the Energy Department deputy undersecretary, told the public in Carlsbad on March 8. But less than two weeks later, New Mexico seemed to have the last word on the immediate response to the accident, when it cancelled its permit for additional disposal at WIPP.

More than a month after the fire, WIPP remains closed, and what happened underground remains unclear. It is not known whether the leak and the truck fire are connected; a waste-drum explosion or the collapse of a roof of one of the facility's storage chambers could be to blame for the radiation event. As Energy Department contractors send robots to explore WIPP's caverns, the future of the world’s only operating high-hazard radioactive waste repository is uncertain.

What WIPP does, and what it contains. In 1979, Congress authorized the design and construction of WIPP, planned to be a repository for a class of waste known as transuranic (TRU)--that is, radioactive elements heavier than uranium on the periodic chart, including plutonium, americium, curium and neptunium¬and generated by the US defense effort after 1970. A bedded salt formation was chosen as the site of the project because of its presumed long-term stability and self-sealing properties. After several long-running legal challenges, Congress authorized the opening of WIPP in 1992 and set a cap of 175,000 cubic meters of waste to be disposed. Seven years later, WIPP began to receive wastes.

The end of the Cold War and the downsizing of the US nuclear weapons complex expanded WIPP’s mission to include excess plutonium. Instead of just contaminated rags, clothing and equipment, in 1998 the Energy Department decided to dispose of plutonium, originally part of the US strategic stockpile, from the now-closed Rocky Flats site. Some 3.5 tons, or more than 70 percent of the plutonium stored in WIPP, was originally meant to be used in nuclear weapons.

WIPP now holds more than 171,000 waste containers containing approximately 4.9 metric tons of plutonium. With a total cost that the Energy Department estimates at $7.2 billion, WIPP employs some 800 workers. The site involves an ongoing mining operation in which salt is loaded on trucks and conveyed to the surface, to other trucks that dump it in a disposal area. The floor space of the mine is designed to be substantially larger than the Pentagon’s. Waste packages are disposed in a 100-acre area that includes seven “rooms¬each with a footprint as large as three football fields¬ carved out of the salt formation in the deep mine.

The toxicity of plutonium and other transuranics was known to be very high in the early days of nuclear weapons production. But official recognition of the waste hazards they pose did not come until the early 1970’s, when the governor of Idaho threatened to halt waste shipments from the Rocky Flats plutonium-component plant in Colorado to what was then known as the Idaho National Engineering Laboratory for disposal¬effectively disrupting weapons production. Citizens and political leaders of the state, fearful that the wastes could reach the state’s largest fresh water aquifer, became alarmed when, after a major fire at Rocky Flats in 1969, an unprecedented amount of transuranic waste was sent to Idaho for shallow land burial. By 1973, Atomic Energy Commission chair Dixie Lee Ray promised to dispose of these wastes in a geological repository.

Plutonium 239 is a major safety concern because of its high radiation levels and long half-life¬24,100 years. About 200,000 times more radioactive than the commonest naturally occurring uranium, plutonium 239 emits alpha particles as its principal form of radiation. Plutonium inhalation can cause permanent lung damage and even death. When taken in the body, microscopic amounts can penetrate deep into the lungs and deposit, via the bloodstream, in the liver, bones, and other organs.

WIPP receives TRU wastes generated after 1970 and, therefore, represents only a partial solution to the United States military nuclear waste problem. Before 1970, more than 2,000 kilograms of plutonium were dumped into the ground as “low-level” waste at many locations across the country. Because of the high costs for removal and geological isolation of that waste, the Energy Department considers pre-1970 TRU wastes to have been disposed “in-place.” The quantity of pre-1970 plutonium currently in the soil at Energy Department sites is some 1,300 times more than is permitted to leak into the human environment from WIPP, 10,000 years after the repository is closed. With nearly half of these wastes in the soil at Hanford, the Energy Department plans for a significant part of that site to become a de facto “ national sacrifice zone.”

The preponderance of the waste placed in WIPP is considered “contact handled,” meaning that it can be prepared for disposal using conventional excavation and processing practices with a manageably small risk of radiation exposure. Since 1970, tens of thousands of such contact-handled TRU waste containers¬ranging from steel drums to cardboard boxes¬have been stored under just a few feet feet of soil at several Energy Department sites.

But there is also a large inventory of “remote-handled” waste that contains highly radioactive transuranics and other isotopes. This type of waste requires heavy shielding and remotely operated equipment to protect workers from severe exposure. Remote-handled packages can emit potentially lethal doses of radiation as large as 1,000 rem per hour.

What happened at WIPP and why? The mishaps at WIPP prompted several ongoing investigations and led to the removal and demotion of a contract manager employed by the UBS Corporation. The fire is believed to have started when diesel fuel or hydraulic fluid leaked inside a truck's engine compartment. The fire consumed the driver’s compartment and the truck's large front tires, which produced copious amounts of thick black smoke, prompting 86 workers to be evacuated. Six workers were treated at the Carlsbad hospital for smoke inhalation, and another seven were treated at the site. Workers have not been allowed back in the mine since. The fire occurred a little less than half a mile from an air monitor alarm set off by the radiation leak, which was located near the latest room being filled with wastes from Idaho, Savannah River, and Los Alamos sites.

The Energy Department investigation report of March 14 concluded the fire could have been prevented had the contractor and Energy Department site managers bothered, after being repeatedly warned, to remove a buildup of flammable material in the mine, to regularly maintain trucks and equipment, and to correct emergency response deficiencies. Moreover, the automatic fire suppression system had been turned off before the fire.

In 2011, the Defense Nuclear Facilities Safety Board, an independent organization that advises the executive branch about health and safety issues at Energy Department defense nuclear facilities, reported that WIPP "does not adequately address the fire hazards and risks associated with underground operations. ... Of particular concern is the failure … to recognize the potential impact of a fire on WIPP's ability to process waste, and ultimately on the ability to reduce inventories of transuranic (TRU) waste at other [Energy Department] sites.”

Whether the radiation leak and the truck fire inside WIPP are connected remains an unanswered question. Among other possible causes of the leak, a waste drum explosion is now under consideration. Energy Department sites have experienced numerous nuclear-waste container fires and explosions through the years. Waste drums containing transuranics generate hydrogen, methane, and other volatile gases which, if unvented, can build up and, if ignited, explode. The most recent drum fire occurred at Los Alamos in November 2008. To mitigate potential explosion hazards from leaking drums, the Energy Department is required to install 12-foot-thick blast walls at WIPP after a room is closed.

Concerns have also been raised about the possibility of a storage room ceiling or wall collapse. Eventually, when WIPP closes, which is projected to occur sometime after 2030, the salt formation is expected to slowly collapse and seal off the drums of waste. But this was not expected to happen until long after the repository is filled and closed. If a collapse has already occurred, just 15 years after the facility opened, it will raise additional questions about WIPP's ability to ensure engineered barriers and institutional controls will work for a 10,000 year period.

Nowhere else to go? There are more questions than answers as the Energy Department and the Defense Nuclear Facilities Safety Board investigate what happened at WIPP and why. Robotic equipment has been sent into the facility, to be followed in the next several weeks by inspectors wearing protective gear, who will ascertain the extent of contamination before a decision is made on whether to send workers back underground. If there is residual contamination, workers may need protective clothing and respiratory protection. Cleanup of a contaminated underground radioactive waste storage site has never been attempted. It could well prove to be daunting.

At least 66,200 cubic meters of transuranic waste sit at Energy Department sites, awaiting shipment to WIPP. The Energy Department is also considering disposal of 5 tons of excess plutonium now at the Savannah River Site in WIPP. Over the past decade, the department has also been seeking to use WIPP to dispose of the contents of several high-level radioactive waste tanks at Hanford by reclassifying those contents as transuranic waste. WIPP is being eyed as a final resting place for tens of tons of plutonium from dismantled weapons as well, because the Energy Department is backing away from the $30 billion price tag now attached to a plan for mixing the plutonium with uranium and using that mixed-oxide to fuel nuclear power plants.

An extended closure of WIPP would no doubt increase political pressure emanating from Washington state, South Carolina, Tennessee, Texas, Idaho, and New Mexico, none of which wants to be left with large amounts of nuclear waste and nowhere to put it. The stakes are large. The questions are many. Competing forces await answers. Surprises should be expected.

Donations can be sent to the Baltimore Nonviolence Center, 325 E. 25th St., Baltimore, MD 21218. Ph: 410-366-1637; Email: mobuszewski [at] Go to

"The master class has always declared the wars; the subject class has always fought the battles. The master class has had all to gain and nothing to lose, while the subject class has had nothing to gain and everything to lose--especially their lives." Eugene Victor Debs

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