Newswise — The U.S. Department of Energy’s Argonne National Laboratory this week released a pair of studies on the efficiency of shale oil production excavation. The reports show that shale oil production generates greenhouse gas emissions at levels similar to traditional crude oil production. The research, which was conducted in collaboration with Stanford University and the University of California, Davis, analyzed the Eagle Ford shale formation, also called a play, in Texas and the Bakken play mainly in North Dakota. These plays are shale formations with low permeability and must be hydraulically fractured to produce oil and gas.

Eagle Ford and Bakken are the second and third largest oil producing shale formation regions in the United States, during the last three years. Together, Bakken and Eagle Ford in 2014 accounted for 54 percent of oil production and 19 percent of gas production among the top seven production regions.

Light crude oil trapped in rock, such as shale, is called tight oil. Its production is accompanied by a significant amount of energy product, including natural gas, some of which gets flared or vented off at the well site. Until now, little information has existed about how production methods impact greenhouse gas emissions at these sites.

“These two plays produce a large amount of the shale oil for the U.S.," said Michael Wang, a senior scientist at Argonne who leads the Greenhouse gases, Regulated Emissions, and Energy use in Transportation (GREET) model, which incorporated the study results. "These two studies have concluded that the net greenhouse gas intensity of production is similar to conventional production.”

Both studies showed that after taking into consideration flaring and venting of natural gas, the greenhouse gas emissions associated with shale/tight oil production are similar to those generated at conventional crude oil reserves. This emission intensity stays consistent during the lifespan of extraction at the oil play. This contradicts an earlier estimate that the Bakken play might produce greenhouse gas emissions 20 percent higher more than for crude oil production.

“Drilling and fracturing wells for shale oil is more energy intensive than conventional drilling, but these wells have higher productivity and require less energy to produce and process the crude," said Adam Brandt, a professor at Stanford University, lead author on the Bakken study. "Flaring of gas is a key issue in the Bakken, and if flaring were controlled the Bakken crude would have lower emissions than conventional crude.”

The Eagle Ford study looked at crude oil produced from different production zones for 2009–2013. Some zones produced more oil while others produced more gas. The study showed that wells in the gas-rich zone used roughly twice as much energy as wells in the oil-rich zone, which used an average of 1.2 percent of energy produced for production, extraction, and processing. Additionally, the water usage rate was generally higher at the gas-rich wells.

“It was challenging to calculate the net energy use and net greenhouse gas emissions for Eagle Ford because of the wide range of products produced at these places, and there were no publicly available tools for horizontal drilling and hydraulic fracturing,” said Sonia Yeh, lead author on the Eagle Ford study and a researcher with the Institute of Transportation Studies at UC Davis. “The collaboration provided greater transparency and understanding of energy and climate impacts of oil production in these regions.”

These studies calculate energy consumption and greenhouse gas emissions associated with the crude oil and natural gas extraction using the Oil Production Greenhouse Gas Emissions Estimator (OPGEE) model with production data collected for shale oil well operations in both plays. This model estimates energy for the lifecycle from the initial exploration to the refinery entrance gate and includes production, processing and transport.

The research team put the OPGEE-produced results into the GREET model developed at Argonne National Laboratory for modeling the life-cycle GHG emissions.

Argonne is a recognized global leader in analyzing the life-cycle energy and environmental impacts of transportation fuels, ranging from conventional gasoline to biofuels to electricity and hydrogen. The laboratory’s Greenhouse gases, Regulated Emissions, and Energy use in Transportation model is the premier tool for analyzing the environmental footprints of fuels and vehicle technologies. GREET looks at all of the energy inputs for a given fuel pathway, from extraction to transportation, refining and combustion, to determine the full life-cycle energy and emissions impacts.

The research was funded by the Vehicle Technology Office and the Bioenergy Technology Office of the Energy Efficiency and Renewable Energy Office of the U.S. Department of Energy to improve the petroleum baseline estimate that serves as the comparison point for alternative vehicle-fuel pathways.

The full reports can be found online at greet.es.anl.gov: “Energy Intensity and Greenhouse Gas Emissions from Crude Oil Production in the Eagle Ford Region: Input Data and Analysis Methods” and “Energy Intensity and Greenhouse Gas Emissions from Crude Oil Production in the Bakken Formation: Input Data and Analysis Methods”.

Argonne National Laboratory seeks solutions to pressing national problems in science and technology. The nation's first national laboratory, Argonne conducts leading-edge basic and applied scientific research in virtually every scientific discipline. With employees from more than 60 nations, Argonne researchers work closely with researchers from hundreds of companies, universities, and federal, state and municipal agencies to help them solve their specific problems, advance America's scientific leadership and prepare the nation for a better future. Argonne is supported by the Office of Science of the U.S. Department of Energy.

Stanford University, located between San Francisco and San Jose in the heart of California's Silicon Valley, is one of the world's leading teaching and research universities. Since its opening in 1891, Stanford has been dedicated to finding solutions to big challenges and to preparing students for leadership in a complex world. Stanford has over 7000 undergraduates and 9000 graduate students, taught by over 2000 faculty members.

University of California, Davis is a global community of individuals united to better humanity and our natural world while seeking solutions to some of our most pressing challenges. Located near the California state capital, UC Davis has more than 34,000 students, and the full-time equivalent of 4,100 faculty and other academics and 17,400 staff. The campus has an annual research budget of over $750 million, a comprehensive health system and about two dozen specialized research centers. The university offers interdisciplinary graduate study and 99 undergraduate majors in four colleges and six professional schools.

The Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit science.energy.gov.