Petroleum use, greenhouse gas emissions of automobiles could drop 80 percent by 2050


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18-Mar-2013

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Contact: Lorin Hancock
[email protected]
202-334-2138
National Academy of Sciences

WASHINGTON — A new National Research Council report finds that by the year 2050, the U.S. may be able to reduce petroleum consumption and greenhouse gas emissions by 80 percent for light-duty vehicles — cars and small trucks — via a combination of more efficient vehicles; the use of alternative fuels like biofuels, electricity, and hydrogen; and strong government policies to overcome high costs and influence consumer choices. While achieving these goals will be difficult, improving technologies driven by strong and effective policies could make deep reductions possible.

“To reach the 2050 goals for reducing petroleum use and greenhouse gases, vehicles must become dramatically more efficient, regardless of how they are powered,” said Douglas M. Chapin, principal of MPR Associates, and chair of the committee that wrote the report. “In addition, alternative fuels to petroleum must be readily available, cost-effective and produced with low emissions of greenhouse gases. Such a transition will be costly and require several decades. The committee’s model calculations, while exploratory and highly uncertain, indicate that the benefits of making the transition, i.e. energy cost savings, improved vehicle technologies, and reductions in petroleum use and greenhouse gas emissions, exceed the additional costs of the transition over and above what the market is willing to do voluntarily.”

Improving the efficiency of conventional vehicles is, up to a point, the most economical and easiest-to-implement approach to saving fuel and lowering emissions, the report says. This approach includes reducing work the engine must perform — reducing vehicle weight, aerodynamic resistance, rolling resistance, and accessories — plus improving the efficiency of the internal combustion engine powertrain.

Improved efficiency alone will not meet the 2050 goals, however. The average fuel economy of vehicles on the road would have to exceed 180 mpg, which, the report says, is extremely unlikely with current technologies. Therefore, the study committee also considered other alternatives for vehicles and fuels, including:

  • hybrid electric vehicles, such as the Toyota Prius;
  • plug-in hybrid electric vehicles, such as the Chevrolet Volt;
  • battery electric vehicles, such as the Nissan Leaf;
  • hydrogen fuel cell electric vehicles, such as the Mercedes F-Cell, scheduled to be introduced about 2014; and
  • compressed natural gas vehicles, such as the Honda Civic Natural Gas.

Although driving costs per mile will be lower, especially for vehicles powered by natural gas or electricity, the high initial purchase cost is likely to be a significant barrier to widespread consumer acceptance, the report says. All the vehicles considered are and will continue to be several thousand dollars more expensive than today’s conventional vehicles. Additionally, particularly in the early years, the report predicts that alternative vehicles will likely be limited to a few body styles and sizes; some will rely on fuels that are not readily available or have restricted travel range; and others may require bulky energy storage that will limit their cargo and passenger capacity. Wide consumer acceptance is essential, however, and large numbers of alternative vehicles must be purchased long before 2050 if the on-road fleet is to meet desired performance goals. Strong policies and technology advances are critical in overcoming this challenge.

The report identified several scenarios that could meet the more demanding 2050 greenhouse gas goal. Each combines highly efficient vehicles with at least one of three alternative power sources — biofuel, electricity, or hydrogen. Natural gas vehicles were considered, but their greenhouse gas emissions are too high for the 2050 goal. However, if the costs of these vehicles can be reduced and appropriate refueling infrastructure created, they have great potential for reducing petroleum consumption.

While corn-grain ethanol and biodiesel are the only biofuels to have been produced in commercial quantities in the U.S. to date, the study committee found much greater potential in biofuels made from lignocellulosic biomass — which includes crop residues like wheat straw, switchgrass, whole trees, and wood waste. This “drop-in” fuel is designed to be a direct replacement for gasoline and could lead to large reductions in both petroleum use and greenhouse gas emissions; it can also be introduced without major changes in fuel delivery infrastructure or vehicles. The report finds that sufficient lignocellulosic biomass could be produced by 2050 to meet the goal of an 80 percent reduction in petroleum use when combined with highly efficient vehicles.

Vehicles powered by electricity will not emit any greenhouse gases, but the production of electricity and the additional load on the electric power grid are factors that must be considered. To the extent that fossil resources are used to generate electricity, the report says that the successful implementation of carbon capture and storage will be essential. These vehicles also rely on batteries, which are projected to drop steeply in price. However, the report says that limited range and long recharge times are likely to limit the use of all-electric vehicles mainly to local driving. Advanced battery technologies under development all face serious technical challenges.

When hydrogen is used as a fuel cell in electric vehicles, the only vehicle emission is water. However, varying amounts of greenhouse gases are emitted during hydrogen production, and the low-greenhouse gas methods of making hydrogen are more expensive and will need further development to become competitive. Hydrogen fuel cell vehicles could become less costly than the advanced internal combustion engine vehicles of 2050. Fuel cell vehicles are not subject to the limitations of battery vehicles, but developing a hydrogen infrastructure in concert with a growing number of fuel cell vehicles will be difficult and expensive, the report says.

The technology advances required to meet the 2050 goals are challenging and not assured. Nevertheless, the committee considers that dramatic cost reduction and overall performance enhancement is possible without unpredictable technology breakthroughs. Achieving these goals requires that the improved technology focus on reducing fuel use rather than adding greater power or weight, the report says.

It is impossible to know which technologies will ultimately succeed, the report says, because all involve uncertainty. The best approach, therefore, is to promote a portfolio of vehicle and fuel research and development, supported by both government and industry, designed to solve the critical challenges in each major candidate technology. Such primary research efforts need continuing evaluation of progress against performance goals to determine which technologies, fuels, designs, and production methods are emerging as the most promising and cost-effective.

Overcoming the barriers to advanced vehicles and fuels will require a rigorous policy framework that is more stringent than the proposed fuel economy standards for 2025. This policy intervention could include high and increasing fuel economy standards, RD support, subsidies, and public information programs aimed at improving consumers’ familiarity with the new fuels and powertrains. Because of the high level of uncertainty in the pace and scale of technology advances, this framework should be modified as technologies develop and as conditions change.

It is essential that policies promoting particular technologies to the public are not introduced before these new fuels and vehicle technologies are close to market readiness, and consumer behavior toward them is well understood. The report warns that forcing a technology into the market should be undertaken only when the benefits of the proposed support justify its costs.

The study was sponsored by the U.S. Department of Energy’s Office of Efficiency and Renewable Energy. The National Academy of Sciences, National Academy of Engineering, Institute of Medicine, and National Research Council make up the National Academies. They are private, independent nonprofit institutions that provide science, technology, and health policy advice under a congressional charter granted to NAS in 1863. The Research Council is the principal operating agency of the National Academy of Sciences and the National Academy of Engineering. For more information, visit http://national-academies.org. A committee roster follows.

Contact:

Lorin Hancock, Media Relations Officer

Office of News and Public Information

202-334-2138; e-mail [email protected]

Pre-publication copies of Transitions to Alternative Vehicles and Fuels are available from the National Academies Press on the Internet at http://www.nap.edu or by calling tel. 202-334-3313 or 1-800-624-6242. Reporters may obtain a copy from the Office of News and Public Information (contacts listed above).

NATIONAL RESEARCH COUNCIL

Division on Engineering and Physical Sciences

Board on Energy and Environmental Systems

Committee on the Potential for Light-duty Vehicle Technologies 2010-2050

Douglas M. Chapin* (chair)

Principal

MPR Associates Inc.

Alexandria, Va.

Ralph Brodd

President

Broddarp of Nevada Inc.

Henderson

Gary L. Cowger*

GLC Ventures LLC

Bloomfield Hills, Mich.

John M. DeCicco

Professor of Practice

University of Michigan

Dexter

George C. Eads

Senior Consultant

CRA International

Washington, D.C.

Ramon L. Espino

Research Professor

Department of Chemical Engineering

University of Virginia

Charlottesville

John M. German

Senior Fellow

International Council for Clean Transportation

Washington, D.C.

David L. Greene

Corporate Fellow

National Transportation Research Center

Oak Ridge National Laboratory

Oak Ridge, Tenn.

Judi Greenwald

Vice President of Technology and Innovation

Center for Climate and Energy Solutions

Arlington, Va.

L. Louis Hegedus*

Senior Vice President

Research and Development

Arkema Inc. (retired)

Bryn Mawr, Pa.

John B. Heywood*

Professor of Mechanical Engineering

Massachusetts Institute of Technology

Cambridge

Virginia McConnell

Senior Fellow

Quality of the Environment Division

Resources for the Future

Washington, D.C.

Stephen J. McGovern

Principal

PetroTech Consultants

Mantua, N.J.

Gene Nemanich

Director of Hydrogen Systems

Chevron Technology Ventures (retired)

Scottsdale, Ariz.

John O’Dell

Senior Editor

Green Car Advisor

Edmunds.com

Santa Monica, Calif.

Robert F. Sawyer*

Class of 1935 Professor of Energy Emeritus

Department of Mechanical Engineering

University of California

Berkeley

Christine S. Sloane

President

Sloane Solutions LLC

Kewadin, Mich.

William H. Walsh Jr.

Automobile Safety Consultant

McLean, Va.

Michael Webber

Josey Centennial Fellow, and

Professor of Mechanical Engineering

University of Texas

Austin

STAFF

Alan Crane

Study Director


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