The electrification of pickup trucks offers greater reductions in greenhouse gas emissions than the electrification of other light-duty vehicles, research finds.
Light-duty vehicles, including sedans, SUVs, and pickup trucks, are currently responsible for 58% of US transportation sector greenhouse gas emissions. Pickup trucks accounted for 14% of light-duty vehicle sales in the United States in 2020, and the market share of both pickups and SUVs has grown in recent years.
But what does pickup truck electrification mean for the decarbonization of the transportation industry?
University of Michigan and Ford Motor Co. researchers addressed this question in a new study and evaluated the savings in greenhouse gas emissions relative to gasoline-powered pickup trucks. The study appears in the journal Environmental Research Letters.
“This is an important study to inform and encourage climate action. Our research clearly shows substantial greenhouse gas emission reductions that can be achieved from transitioning to electrified powertrains across all vehicle classes,” says study senior author Greg Keoleian, a professor at the University of Michigan School for Environment and Sustainability and director of the Center for Sustainable Systems.
In the study, researchers conducted a cradle-to-grave assessment of the life cycle of pickup trucks and compared the implications of pickup truck electrification to those of sedan and SUV electrification.
With a focus on evaluating greenhouse gas emissions, researchers looked at three different model-year 2020 powertrain options—internal-combustion-engine vehicles, hybrid-electric vehicles, and battery-electric vehicles—for midsize sedans, midsize SUVs, and full-size pickup trucks, accounting for differences in fuel economy, annual mileage, vehicle production, and vehicle lifetime across vehicle classes.
They found that for sedans, SUVs, and pickup trucks, battery-electric vehicles have approximately 64% lower cradle-to-grave life cycle greenhouse gas emissions than internal-combustion-engine vehicles on average across the United States.
“This study can help us to understand the potential impact of electrification from an emissions-reduction perspective, particularly as we introduce new electric vehicles, and how we can continue to accelerate our progress towards carbon neutrality,” says Cynthia Williams, global director of sustainability, homologation, and compliance at Ford.
The study offers several key findings. Researchers, for instance, found that replacing an internal-combustion-engine vehicle with a battery-electric vehicle results in greater total tonnage of greenhouse gas emissions reductions as the vehicle size increases, due to the greater fuel consumption of larger vehicles.
Though the percentage savings is about the same across vehicle classes, on average, replacing an internal-combustion-engine sedan with a battery-electric sedan saves 45 metric tons of carbon dioxide equivalent; replacing an internal-combustion-engine SUV with a battery-electric SUV saves 56 metric tons of carbon dioxide equivalent; and replacing an internal-combustion-engine pickup with a battery-electric pickup saves 74 metric tons carbon dioxide equivalent over the lifetime of the vehicles, says first author Max Woody, research specialist at the university’s Center for Sustainable Systems.
The researchers also found that battery-electric vehicles have larger greenhouse gas emissions in their manufacturing than internal-combustion-engine vehicles, due to battery production, but this impact is offset by savings in their operation. For battery-electric vehicles and internal-combustion-engine vehicles, the break-even time is 1.2 to 1.3 years for sedans, 1.4 to 1.6 years for SUVs, and 1.3 years for pickup trucks, based on the average US grid and vehicle miles traveled.
“This study expands upon previous studies that have focused on comparing battery-electric vehicle sedans to their internal-combustion-engine or hybrid counterparts,” Keoleian says. “We report emissions for vehicle production, use, and end-of-life stages on a per-mile basis and over the total vehicle lifetime.
“In addition, we analyzed the regional variation in emissions considering differences in electricity grid mixes and ambient temperatures, and we also explored the effects of the rate of grid decarbonization on emission reduction.”
Vehicle emissions vary across the country, as different temperatures and different drive cycles affect a vehicle’s fuel economy. For electric vehicles, the greenhouse gas emissions intensity of the local electricity grid is also an important factor. The study developed maps to show the lifetime grams of carbon dioxide equivalent/mile for each powertrain (internal-combustion-engine vehicles, hybrid vehicles, and battery-electric vehicles) and vehicle type (sedan, SUV, and pickup truck) by county across the United States.
Researchers found that public concerns about battery-electric vehicles having higher emissions than internal-combustion-engine vehicles or hybrids are largely unfounded, as battery-electric vehicles outperform hybrids in 95%-96% of counties, while battery-electric vehicles outperform internal-combustion-engine vehicles in 98%-99% of counties, even assuming only modest progress towards grid decarbonization.
Charging strategies can further reduce battery-electric vehicle emissions. The study found that charging during the hours of the day with the lowest grid emissions intensity can reduce emissions by 11% on average.
“Deployment of electric vehicles and expansion of renewable energy resources like solar and wind should be done at the same time,” Woody says. “The benefit of each is increased by the development of the other.”
Support for the work came from Ford Motor Co. through a Ford-University of Michigan Alliance Project Award.
Source: Lori Atherton for University of Michigan