Fracking and the economy

I continue to remain interested in the effects of shale oil on the U.S. economy, even as the price of gas is reasonably low and the price of West Texas Intermediate is 42 bucks. A recent report by Dartmouth/NBER on the effects of fracking (via Reuters):

...Researchers conducting the National Bureau of Economic Research study analyzed data from over 3,000 U.S. counties and determined that within 100 miles of new production, $1 million of extracted oil and gas generated $243,000 in wages, $117,000 in royalties and 2.49 jobs. 

"Aggregating to the national level we conclude that aggregate employment rose by 725,000 jobs due to fracking, causing a reduction in the U.S. unemployment rate of 0.5 percent during the Great Recession," according to the study...

Gotta say, 725,000 jobs is a lot of jobs, even if a kajillion of them were in Williston, ND. I wonder how long this will last...

Vox is wrong: the bad actor in Bakken shale is the gases, not benzene

UPDATE: Brad Plumer has made the correction. Thanks, Brad!

Vox's Brad Plumer had a nice explainer on oil trains derailing and exploding (written in light of the latest West Virginia derailment) which contained this line (emphasis mine): 

1) The newer oil is more volatile: Crude oil from the Bakken formation in North Dakota — where much of the new oil-by-rail is coming from — often contains extra chemicals like benzene that make the crude more flammable. The trains in the Lac-Mégantic and West Virginia accidents were both carrying crude from this region.

(Extra chemicals! N.B. there's always benzene in crude, I think.)

His source for this is (ultimately) desmogblog, which is better known as a climate change blog, I think. Here's their explanation:

...“Hazardous Air Pollutant (HAP) emissions are expected from the proposed equipment,” explains the Marquis permit. “There will be evaporative losses of Toluene, Xylene, Hexane, and Benzene from the crude oil handled by the installation.” 

Benzene is a carcinogen, while toluene, xylene and hexane are dangerous volatiles that can cause severe illnesses or even death at high levels of exposure.   

Scientific Vindication 

In a December 31 Google Hangout conversation between actor Mark Ruffalo, founder of Water Defense, and the group's chief scientist Scott Smith, Mr. Smith discussed the oil samples he collected on a previous visit to North Dakota's Bakken Shale. 

“What I know from the testing I've done on my own — I went out to the Bakken oil fields and pumped oil from the well — I know there are unprecedented levels of these explosive volatiles: benzene, toluene, xylene,” said Smith. 

“And from the data that I've gotten from third parties and tested myself, 30 to 40 percent of what's going into those rail cars are explosive volatiles, again that are not in typical oils.”

First, to a lab chemist, calling xylene a volatile is sort of odd (it has a boiling point of 140°C!), but everything is relative. When you're used to doing most of your reactions in THF (boiling point of 66°C) or say, heptane (boiling point of 98°C), then 140°C sounds pretty high. That said, EPA counts these aromatic solvents as VOCs, so that seems reasonable.

(Also, when your chief scientist has a degree in economics... I digress.)

But that said, I think there are many, many, many more volatile compounds than benzene in Bakken crude. This has been covered extensively by the Wall Street Journal -- here's a some nice examples of some of their explanations of the chemistry. From a February 2014 article by Russell Gold:

The rapid growth in Bakken production has far outpaced the installation of pipelines, which traditionally had been relied on to move oil from wells to refineries. Most shale oil from Texas moves through pipelines, but about 70% of Bakken crude travels by train.
Bakken crude actually is a mixture of oil, ethane, propane and other gaseous liquids, which are commingled far more than in conventional crude. Unlike conventional oil, which sometimes looks like black syrup, Bakken crude tends to be very light. "You can put it in your gas tank and run it," said Jason Nick, a product manager at testing-instruments company Ametek Inc. "It smells like gasoline."

Here's a July 2014 where Russell Gold and Chester Dawson say the same thing*:

Stabilizers use heat and pressure to force light hydrocarbon molecules—including ethane, butane and propane—to form into vapor and boil out of the liquid crude. The operation can lower the vapor pressure of crude oil, making it less volatile and therefore safer to transport by pipeline or rail tank car.

And yet another great explanation* by Alison Sider and Nicole Friedman:

There are geologic reasons that the new oil is particularly gassy and volatile. Over millions of years, organic material turns into a brew of hydrocarbons: crude oil, natural gas and other gas-infused liquids. The longer that fossil-fuel mixture cooks underground—in intense heat and under tremendous pressure—the more molecules escape from their source rocks and migrate to reservoirs where there is room to move around, says Scott Tinker, the state geologist for Texas. 

In those reservoirs, the oil and gas separate into less-dense gas on top and heavier crude oil below, much like a shaken vinaigrette settles into distinct layers. 

But shale rock is so dense that much less oil and gas escapes from it. The energy industry must frack shale to create tiny fissures so that oil and gas can flow out. Those minuscule pathways let only the smallest molecules rise, which is why large volumes of gas and the lightest liquids are coming out of the ground. 

In most cases, ultralight oil doesn't look like black gold. In fact, it can be as clear as water and some oil from the Eagle Ford Shale in Texas brims with so much dissolved gas that it bubbles, giving the appearance of boiling at room temperature. 

That gas makes ultralight shale oil highly combustible in a way conventional crude is not. In the past year, derailments of trains carrying light crude have resulted in spectacular blowups, including an explosion that killed 47 people in Quebec last July.

Ethane, propane and butane have boiling points of -89°C, -42°C and -1°C respectively. It seems intuitive to this chemist that they'd be far more flammable and more likely to burn and explode than benzene, toluene and xylenes. Vox is wrong, I think, and they should correct this.

(I should note that WSJ itself (and me, I guess) initially fell into this trap. I guess benzene just sounds like a bad actor.)

*How to get around the WSJ paywall -- search for the title of the article.

Hydraulic fracturing wastewater and #chemjobs

Whatever you think of hydraulic fracturing, there's one thing for certain -- there are probably a lot of new jobs in the field. From this week's Chemical and Engineering News article by Melody Baumgardner (emphasis mine):

There’s a lot of water to treat. Hydraulic fracturing requires between 3 million and 5 million gal of water per gas well. The water is combined with fracturing chemicals and a sand or ceramic proppant and then pumped into the horizontal branches of the well. The proppant props open fractures in the shale, allowing gas that has been trapped for eons to flow out. After fracking, roughly 35% of the water returns to the surface as flowback in the first weeks. Additional liquid known as produced water—a mix of fracking fluid and groundwater—comes up with the gas for most of the life of the well. 

Hydraulic fracturing got its start in western states, where oil and gas drillers pump untreated wastewater into nearby wells driven deep into porous rock. For decades, deep-well injection has been the first choice for disposal because of its low cost. But the Marcellus areas of Pennsylvania and West Virginia have a geology that is not suited to deep-well injection. To dispose of the water off-site would require around 40 truck trips every day for weeks or months. That is costly, and energy companies can literally wear out their welcome when using local roads. 

In contrast, the goals of wastewater treatment are to reuse, recycle, or reduce the water that comes out of the well. Chemical firms that specialize in water treatment such as Kemira and Ecolab’s Nalco unit; equipment makers including GE and Siemens; and service providers, both large and small, customize their offerings depending on the water’s contents and where it is destined to go. The main consideration in selecting technologies, all agree, is cost. 

With prices for natural gas at a historic low of less than $3.00 per thousand cu ft, energy firms are compelled to select the cheapest legal alternative. “My biggest competitor is a hole in the ground,” says Mark Wilson, marketing director for unconventional gas at GE Power & Water. “We are looking for more energy efficiency and lower capital costs.”

I think one of the few bright spots in the #chemjobs field has been Nalco, which has been hiring consistently over the last few years. Read the whole thing, especially if you're interested in learning about some of the actual environmental consequences of hydraulic fracturing.