The Boom: How Fracking Ignited the American Energy Revolution and Changed the World
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These disposal wells, even overlooking the inherent problem of taking drinkable water and sending it into permanent exile, can lubricate existing faults and cause earthquakes. “Man-made seismicity” and “induced seismicity” are the polite terms for this phenomenon. While the tremors aren’t large, they are nonetheless unsettling for longtime residents of Dallas and Columbus, Ohio, who are growing accustomed to feeling small rumbles under their feet.
Getting the fresh water to a well requires considerable truck traffic. For the Matt 2H on my parents’ property, about 350 trucks delivered water from the Susquehanna River, which is thirty miles away. Another 75 trucks traveled sixty miles from Tunkhannock Creek, and 10 trucks from nearby towns. More trucks hauled in a small factory of equipment needed to drill and fracture the well.
So far, the shallow aquifer that supplies drinking water on my parents’ property and neighboring farms hasn’t turned briny. Tests for contaminants have been negative. The well itself descended 7,200 feet. If it was built correctly, it is doubtful that man-made fractures created any new pathways for existing pollutants, or chemicals used to create the well, to rise up into the aquifer. It isn’t impossible, but independent studies in neighboring counties called such an occurrence “unlikely” and haven’t turned up any evidence of this taking place.
If the fracking didn’t create any pollution pathways, perhaps the well itself did. The layers of cement and steel pipe inserted into the wellbore and designed to protect shallow drinking water aquifers don’t always work. My father asked for information about what tests Chesapeake ran on the well to determine if the cement held, but he gave up asking after getting the runaround for a couple weeks. Even if the well was good on day one, what will happen to the Matt 2H after a decade, or decades, of the pipes and cement sitting in a hot environment with corrosive liquids? Was Chesapeake in a rush to finish the well and move on to the next? I don’t know. State inspectors cited the company for failing to follow “best management practices” to protect a nearby stream. What the inspectors saw on the surface led to violations, but what about what was below and out of sight?
There’s another question about the well—and many others like it. When Chesapeake completed the Matt 2H, flushing out the water it injected underground, how much natural gas was allowed to vent into the atmosphere? How much escaped from the pipelines that delivered it around the country? Methane, the main ingredient of natural gas, is a potent greenhouse gas. Releasing it adds to the carbonization of the atmosphere and contributes to climate change. Indeed, if too much natural gas leaks out, the benefits of making electricity from gas versus coal can disappear. I have no way of knowing how much methane escaped from the Matt 2H. When future wells are drilled on the pad on the Farm, federal rules that go into effect in 2014 will require “green completions” to capture this methane. Some companies already use this equipment and report that not only is most of the methane captured, this approach often pays for itself by avoiding the expense of buying the diesel otherwise needed to fuel drill-site machinery.
In July 2011, a month before fracking of the Matt 2H began, the lead author of a large study on natural gas told the US Senate Committee on Energy and Natural Resources that there are benefits and risks associated with fracking. The risks, said Ernest Moniz, then a professor at the Massachusetts Institute of Technology, are “challenging but manageable. In all instances, the risks can be mitigated to acceptable levels through appropriate regulation and oversight.” As he said in a speech a year later, “All of these are manageable, which should not be confused with managing them.” Three months after he made these comments, Moniz was nominated to become secretary of energy. Both the federal government and state governments are taking steps to identify problems and devise fixes. The environmental impact is improving. But more can be done and, as long as regulators and the industry don’t shy away from problems, can continue to be done.
Thanks to fracking, the United States is producing more natural gas than ever. The same technology used to get gas out of shale is now being used to get oil as well. In the summer of 2013, the United States pumped nearly 7.5 million barrels a day of crude oil, a level unseen since 1990. North Dakota, home to the Bakken Shale, was producing 875,000 barrels a day, up from 150,000 barrels five years earlier. For decades, the United States has imported millions of barrels of oil every day. Imports are now falling. While it seems unlikely that America will ever become “energy independent,” it is certainly unwinding its dependence on foreign suppliers in the Middle East and Africa. For generations, the United States has used its military might to keep oil flowing, fighting wars and patrolling sea lanes. Maybe this era will now come to an end. By 2020, America could become the largest global oil producer.
This is a stark change from the past, when so much energy production was outsourced. US energy consumers were able to use vast amounts of oil and gas without having to confront the impact or legacy of their addiction. A few years ago, I flew over Nigeria’s coastal mangrove swamps in a helicopter. The vegetation on the sides of the Niger River was blanched white and denuded of leaves. It felt like I was looking at a black-and-white film. After decades of oil development, and the extraction of more than $1 trillion worth of oil, Nigeria struggles with rampant corruption and internal conflict. It remains a poor nation by any measure. The Niger Delta was the source of nearly 8 percent of the oil imported by the United States from 1981 to 2011. In the first half of 2013 it was 4 percent and falling.
Fracking means that the United States is producing more and more of the energy it consumes in its backyard. That didn’t work out too well for Ottis Grimes. But there is no question that the localized environmental impact is significantly less than in 1919 Burkburnett, or modern-day Nigeria.
Drilling wells in a more environmentally responsible manner isn’t enough for some fossil-fuel critics. They argue that burning coal, oil, and gas is releasing too much carbon and accelerating the unpredictable consequences of climate change. But not all fuel is equal in this measure. To achieve the same amount of energy, burning coal generates 42 percent more carbon dioxide than crude oil, which itself generates 18 percent more than natural gas. Critics argue that slowing the rate at which carbon is building up in the atmosphere, by burning gas instead of coal, is a half measure, and the Earth is too far into climate change for this kind of incremental progress. What is needed, they contend, is a wholesale switch to fuels that don’t emit any carbon.
Sometimes I wonder what the energy landscape would look like if the industry couldn’t frack shale rocks; if all that oil and gas were still locked away out of reach. Would there be more wind and solar power? Would we be putting liquefied corncobs and prairie grass into our fuel tanks? Would we have found ways to be more fuel efficient, investing in public transportation and insulated windowpanes?
I suspect that America would be importing huge amounts of natural gas from overseas along with the fleet of tankers that brings crude oil. Fracking has not derailed the growth of renewable energy. Electricity from renewables, power sources that emit no carbon, has grown fast. The wind provided three-tenths of 1 percent of US power a decade ago. It is now about 4 percent. Considering that American energy consumption is Brobdingnagian, that’s historic growth. Solar is also growing but remains much smaller.
Energy systems change when something better and cheaper comes along. New England’s whalers stopped harpooning when refined petroleum proved a better light source. Crude oil replaced coal in trains and boats in the first couple decades of the twentieth century because it was a more compact, capable fuel. Natural gas is making inroads because fracking allows it to be abundant and cheap, at least in the United States. Some believed that the twenty-first century belonged to renewables—and it might yet—but fracking has breathed new life into fossil fuels.
Fracking is a challenge to renewable energy systems such as wind farms and solar arrays. The glut of inexpensive gas has made it hard for renewable energy to compete on the nation’s power grid
s. But this competition is also forcing wind and solar to get better and, arguably, helping accelerate the maturation of these technologies. The abundance of inexpensive natural gas helped cushion the sticker shock of higher-priced renewables. Wind and sun are power sources that turn on and off. The wind doesn’t always blow, and clouds can block the sun. For the power grid to function as we expect, there needs to be something to back up this intermittent renewable energy. Coal and nuclear power plants aren’t well suited for the job. They don’t like to be turned on and off quickly. But natural gas power plants are more nimble and can hold together a mélange of renewable and fossil fuels. This possible future is on view in Texas, which leads the nation in wind power and natural gas production. One study, paid for by renewable energy advocates, concluded the path to low-carbon power generation will require both gas and renewables working together.
The global energy system is vast. It won’t change quickly. It is the foundation of modern life, and due to climate change, it poses a threat to modern life. The energy unearthed by fracking is both a once-in-a-lifetime opportunity and an enormous challenge. The rise of fracking is a story of ambition and resourcefulness. It is a tale that could occur only in the freewheeling United States, a nation of an enormous energy appetite, with no discernible policy on providing that energy, and a willingness to turn its back on Ottis Grimes. The Earth is warming, and once the source rock is depleted, the era of fossil fuel will end whether we are ready or not. Fracking has changed the energy industry and is changing the world around us. It is here to stay.
3
EVERYONE COMES FOR THE MONEY
A few miles south of Killdeer, North Dakota, amid rolling grassland that stretches out of sight in all four directions, two dozen men huddle close together to hear Josh Byington over the blustery prairie wind. “Welcome out here, gentlemen,” says Byington, his hooded eyes peering around from under a hard hat. Everyone but him wears identical dark blue coveralls with silver reflective stripes around their arms. Each has an American flag patch on the right arm and the North Dakota state flag on the left arm. Some workers left their hard hats unadorned except for the name of their employer. Others personalized their hats with stickers. One guy had “Frackn8r” on his hat. Another: “Coon Ass.”
Byington is youthful and trim. Only when he takes off his hard hat (sticker free) do you see that his sandy hair is being gradually overrun by white. Just shy of forty years old, he has two decades’ experience in the oil fields of North Dakota, Wyoming, and Colorado. At this prefrack safety meeting, his word is final. Talk to the workers whose shift is ending, he urges. Learn if there have been any problems. When we’re pressuring the pipe to test it, don’t stand near the iron. Be careful. Be smart.
“Pay attention to what is going on. This is big business. Hit the wrong switch, it could be your life or someone else’s.” He pauses. “No one gets hurt today, right?”
There are murmurs of assent. One worker yells, “Exactly!”
“All right, gentlemen,” Byington says as he looks around, “let’s go have some fun.”
I have come to North Dakota to observe the fracking of the Irene Kovaloff 11-18H, a well on the southern edge of the Bakken Shale. There is nothing exotic about the well. It is one of a crowd of one hundred wells that will be fracked in the United States on this particular day in October 2012, ten in North Dakota alone. I could have chosen any number of places to witness a frack. But North Dakota offered an unvarnished view of the industry at full throttle. Trucks crowded the roads. In nearby Dickinson, where I stayed for a few days, the city engineer had resigned a week earlier, citing his increased workload and stress. That’s what happens when five thousand new residents move into a city in two years, making one of every four Dickinsonians a recent arrival. In the midst of a sluggish national economy, locals advertised five openings for every person seeking a job.
Energy companies have come to North Dakota because when they frack the Bakken, light sweet crude oil comes out of the rock. Other shales offer mostly natural gas, which by the middle of 2012 was so plentiful there was a glut. So the rigs and the frack crews migrated to the Bakken. The industry is moving so quickly that the pipe layers can’t keep up. Trucks haul the crude to rail depots, where it is loaded onto railroad cars. The wells here produce a bit of natural gas also, and no one wants to wait around for a connection to a gas pipeline, so they flare it off. At night, the onyx sky flickers with gas being burned off. One night I drove out from Williston, another oil boomtown, in search of a flare and found one within five minutes. Flames roared in a pit on the side of the road like a giant, unattended bonfire.
Over my journalism career, I have visited dozens of wells. But I had never spent time at the well as it was fracked. I felt a bit like a baseball fan who scanned the box scores and followed the standings closely but had never watched a game. I wanted to take my seat and settle back to watch the whole nine innings. Getting a ticket, however, wasn’t easy. I called several companies active in the Bakken. They turned me down. One told me it was too busy to have its people take time off to “babysit” a visitor. Another said it just wasn’t interested. Finally, Marathon Oil, a Houston corporation that generates an annual profit larger than the gross domestic product of some small countries, agreed to let me spend time on a frack job. The decision went all the way up to the chief executive. He decided that the industry had been hurt by its secrecy. When I got the okay, I went out and purchased a pair of steel-toed work boots.
A few weeks later, I waited in a North Dakota hotel room. The prairie winds had been near hurricane strength for an entire day, causing operations to come to a standstill. When my cell phone rang, a Marathon official told me that the winds had died down enough to allow the fracking of the Irene Kovaloff. I hopped in my rental car and headed north from Dickinson to meet my Marathon handlers.
Josh Byington oversees the movements of the couple dozen coverall-clad workers. His directive is simple enough: force more than one million gallons of liquid into the Irene Kovaloff under enough pressure to crumple the toughest car Detroit can turn out. Until his replacement arrives later that night, he makes sure the cocktail of water, sand, and chemicals was mixed just right. He checks that every flange is in place and every bolt secure. On this cold October day, the Bakken rock underfoot is the same thick, impermeable layer that it has been for the past fifty million years. By the time Byington has slept for a few hours and returned for his next shift, a full twenty-four hours after the fracking began, this section of the Bakken will be filled with thousands of tiny fractures, smashed into pieces like a shattered dinner plate. A week later, the valves atop the well will be opened, and crude oil will begin to seep through these new networks into the well. It will be pumped to the surface and, after being processed in a refinery, will end up as gasoline in automobile tanks and fuel in the airplanes overhead. By then, Marathon will have fracked several more wells.
The Irene Kovaloff, a recently drilled, long, and narrow hole in the ground, went straight down two miles until it reached the Bakken Shale, and then made a gradual 90-degree turn and continued for another two more miles in a southerly direction. Once fracked, the Irene Kovaloff dribbled forth a thousand barrels a day of crude for the first few weeks. Then the oil flow started to decline. By itself, the Irene Kovaloff is a drop in the global bucket. But Irene isn’t alone. Nearby is her sister, the Viola Koberstine 34-7H. And not far away are relatives and neighbors: the Willard Kovaloff 21-17H, the Darcy Dirkach 14-12H, the Louie Hendricks 24-20H, the Wm. and Agnes Scott 14-25H, and the his-and-hers wells, the Tom Steffan 21-27H and the Deanna Steffan 44-22H. And so forth and so on across the prairie. Compare the list of well names to North Dakota homesteaders, and there is significant overlap.
Before workers transform the Irene Kovaloff into a producing oil well, they must make sure everything is secure and ready. When the prefrack safety meeting ends, a class system among the workers becomes visible. Most of the men head in one direction, where they check water
levels in the rows of blue trailers, stand amid clouds of silica dust to make sure the sand doesn’t fall off the conveyor belt, or tend to the dozens of machines. They spend their shift smelling musty diesel and tie their hoodies around their faces to keep out the cold. It is in the high thirties, but the constant wind makes it feel significantly colder. A smaller group heads in another direction and climbs a few steps into a temperature-controlled trailer called the data van. They spend their shift inside, peering out of thick-paned windows at the well, giving orders through headsets. They take off their hard hats and strip down to T-shirts under their coveralls. There is a coffee urn at their disposal. A car stereo bolted into a wall panel keeps them entertained during overnight shifts. On a recent night, Pink Floyd’s The Dark Side of the Moon accompanied a frack. The next night it was Ted Nugent. The guys outside hope to work their way into a data van job.
Byington heads inside. He is at the top of the pyramid, and the only person not wearing coveralls. He is the “company man,” the oil company’s top representative on a job site. But Marathon Oil contracts out this work, and even though Byington is Marathon’s man on the frack site, he works for StimTech, a company in Rock Springs, Wyoming, that provides a variety of skilled workers and well services to the industry. His job title is consultant. Marathon has invested $9 million to lease the location as well as drill and frack the Irene Kovaloff. The company usually has one employee at the frack site, responsible for health and safety. This arrangement is the modern corporate approach to oil production. The company subcontracts out nearly everything and leaves almost nothing to discretion. For this well, engineers in Houston created a “prog,” a forty-page document that provides step-by-step directions. Workers will frack the well thirty times. Each frack has six distinct steps. It’s all in the prog: when to switch chemical recipes, when to release four different gradients of sand, how much pressure to use. All of these instructions were uploaded into data van computers. “Marathon cooks this up, kicks it up to us, and we try to execute it to a tee,” says Byington.