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NREL: Co-Optima Crosses the Finish Line

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Just as the wheels keep turning on cars, trucks, and trains, the planet keeps spinning in its orbit. All the while, climate change is accelerating, along with the dire need to cut greenhouse gas (GHG) emissions responsible for global warming. Transportation activity releases 1.5 billion tons of GHGs into the atmosphere every year.

The U.S. Department of Energy (DOE) Co-Optimization of Fuels & Engines (Co-Optima) initiative recently wrapped up six years of fuel and engine research designed to more rapidly reduce dependence on international petroleum and cut emissions, while slowing global warming. DOE’s National Renewable Energy Laboratory (NREL) played a major role in the collaborative undertaking. Findings are now available in a recently released report.

“The team’s discoveries can make a real difference in just a few short years,” said Co-Optima Leadership Team Member, NREL Senior Research Fellow, and Advanced Fuels Combustion Platform Leader Robert McCormick. “These emissions and fuel economy benefits don’t require huge changes to infrastructure and only call for relatively minor changes to engine and vehicle fuel system designs.”

Fewer Emissions, Greater Efficiency for All Types of On-Road Vehicles
Photo montage. Aerial photos of cars on highway; freight train on track; cargo ship in water; truck on highway.
Co-Optima breakthroughs hold promise to slash emissions from all forms of transportation. Photos from Getty Images
Experts from NREL and eight other national laboratories set out to give American industry and policymakers the scientific knowledge, data, and tools needed to decide which new fuel-engine combinations could most realistically benefit drivers, businesses, and the environment.

Co-Optima research explored solutions for all classes of on-road vehicles: light-, medium-, and heavy-duty. NREL’s scientific investigation combined laboratory assessments with modeling, simulation, and analysis.

The results? Identification of domestically sourced, bio-based fuel components that meet or exceed DOE’s target of 60% fewer GHG emissions than those generated by petroleum-based fuels used in on-road vehicles.

Co-Optima research also revealed ways to improve fuel economy by 10% for today’s turbocharged car engines and an extra 14% using advanced engines. In addition, the scientists explained how it might be possible to eliminate more than 99% of some of the most harmful freight truck criteria pollutants at the same time as improving engine efficiency by up to 4%.

“When we launched the Co-Optima initiative, we just hoped we could move the needle a little bit,” said NREL Vehicle Technologies Program Manager John Farrell. “While reaching net-zero transportation emissions means many sweeping changes, such as eventually a huge shift to electric vehicles, co-optimization can make a real difference in the meantime—especially for hard-to-electrify vehicles.”

Farrell served as Co-Optima project leader from its early planning stages and 2015 launch through December 2018.

Fuel Components Made From Sustainable Domestic Sources
Co-Optima researchers focused on identifying and understanding fuel components known as blendstocks, which can be combined with existing fuels to improve vehicles’ carbon footprint and engine performance. The team screened more than 1,000 options to pinpoint high-performing blendstocks that can potentially be produced at commercial scale from the estimated billion-ton annual supply of domestic biomass resources.

“While we might not ever be able to turn absolutely all of the one billion tons of sustainable feedstock into transportation fuel,” McCormick said, “we now have a solid understanding of what sources will come closest to delivering the characteristics, performance, and environmental benefits needed, while also being viable for commercial production and affordable prices at the pump.”

Along the way, Co-Optima scientists, engineers, and analysts from NREL and other laboratories invented new methods and tools to expand understanding of combustion and fuel properties. NREL’s Co-Optima fuel chemistry research included:

Mapping connections between fuel molecular structure and properties, as well as between fuel properties and combustion
Finding fuel-engine combinations capable of reducing emissions of GHGs and criteria pollutants including soot, nitrogen oxides, and hydrocarbons
Developing a speedy and accurate online tool to identify the molecular structure of these promising blendstock candidates in seconds rather than days
Applying advanced computational methods to discover engine control strategies that can dramatically reduce emissions with sustained power
Using enhanced modeling capabilities to simulate deployment of vehicles with co-optimized fuels and engines, revealing the potential to decrease emissions.
Options To Benefit Producers, Consumers—and the Planet
Making sure new fuels and engines can be scaled up for commercial production, will be compatible with fueling infrastructure and vehicle components, and can be produced at competitive cost are all vital factors in bringing cleaner, more efficient transportation solutions to market. Co-Optima researchers from NREL and other laboratories used techno-economic and life cycle analyses to assess blendstocks’ technology readiness, market viability, and environmental impacts.

Most candidate blendstocks offered favorable economic metrics, four with target case prices below $4 per gasoline gallon equivalent (GGE). Blendstock candidates produced from corn stover, woody biomass, and used cooking oil show potential to be produced at commercial scale and deliver competitive prices at the pump. Renewable diesel produced from wet wastes and used cooking oil using certain methods delivered the most favorable economic potential and emissions reductions.

NREL’s contributions to this analysis work included:

Identifying primary cost drivers tied to production approaches for bioblendstocks to determine which might have the greatest economic impact
Conducting comparative assessments of a variety of feedstocks, conversion pathways, and fuel chemistries to determine viability of commercial-scale production
Developing an analysis method that evaluates economic benefits for refineries and automotive manufacturers in the form of cost savings and profitability
Creating a new model to analyze the ability of Co-Optima vehicles to compete with other low-emission technologies over time, given changes in costs, policy, and other factors
Integrating vehicle and fuel deployment modeling and analysis to better identify potential market barriers and strategies for overcoming them.
Infographic with roundup of Co-Optima findings and impact related to environmental sustainability Infographic with roundup of Co-Optima findings and impact related to the scientific process
Infographic with roundup of Co-Optima findings and impact related to energy efficiency Infographic with roundup of Co-Optima findings and impact related to economic vitality
Strategies explored by Co-Optima have the potential to deliver significant efficiency and environmental benefits.

The Road Ahead to Net-Zero Emissions
The combination of sustainable fuels uncovered by Co-Optima research can reduce the emissions of vehicles now, while enabling a faster transition to net-zero-carbon emissions for on-road transportation in the future. Efficient pollution-reducing fuels and engine technologies identified by Co-Optima researchers may also help cut pollution from marine, rail, off-road, and aviation engines.

Fuels produced from biomass—such as forestry and agricultural byproducts, algae, discarded cooking oil, and even manure—could eventually meet 100% of future demand for air, marine, and rail fuel. That would still leave enough to meet the fuel needs of long-haul freight trucks that are harder to electrify.

By reducing criteria pollutant and GHG emissions, Co-Optima approaches can also help diminish the concentration of poor air quality near highways and transportation hubs that are frequently located near underserved populations. This can help limit the impact of climate change on vulnerable communities. In addition, biofuel production can boost the economy and create jobs in rural areas.

NREL and its partners know that many challenges remain in the effort to reach net-zero emissions by 2050.

“Manufacturers still need to see what other changes will be necessary to ensure new sustainable blendstocks are compatible with commercial engines,” McCormick said. “Once that happens, the fuel–engine combinations identified through Co-Optima can make important contributions to the nation’s battle against climate change.”

Sponsored by DOE’s Vehicle Technologies Office and Bioenergy Technologies Office, Co-Optima partners include NREL as well as Argonne, Idaho, Lawrence Berkeley, Lawrence Livermore, Los Alamos, Oak Ridge, Pacific Northwest, and Sandia national laboratories, plus more than 40 university and industry partners.

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