Energy Biosciences Institute

Principal Investigator: Arpad Horvath, UC Berkeley
Co-PI: Thomas McKone, Lawrence Berkeley National Laboratory
Faculty Collaborators: Maximilian Auffhammer, Peter Berck, Tim Lipman, Daniel Kammen, William Nazaroff, Margaret Torn
Postdocs: Umakant Mishra, Nick Santero
Research Associates: Eric Masanet, Agnes Lobscheid
Graduate Students: Catherine Almirall, Audrey Barrett, Matt Bomberg, Kevin Fingerman, Calanit Saenger, Corinne Scown, Bret Strogen, Joshua Apte, Ted Huynh, Omer Shalev
Undergraduate Student: Norman Wen

Successful deployment of biofuels requires research to overcome technical barriers in the path from sunlight to fuels via biological systems. However, there are other barriers that can often impose constraints more challenging than those related to technical feasibility. These are the constraints imposed by cost, resource limitations, health risks, climate impacts, and nutrient-cycle disruption, among others. Addressing the world’s need for near-term, cost-effective, and reliable technologies for biofuels requires research to address in parallel technical, social, economic, and environmental barriers.

The extraction, production, and utilization of fossil-based transportation fuels have major health and environmental consequences. In the search for carbon-neutral alternatives to petroleum, biofuels have emerged as a technologically feasible option. But current methods to measure, evaluate, and regulate the ecological and human health impacts of biofuels are inadequate. Because transportation fuels are so heavily used and because the environmental consequences of the current system are so large, it is inevitable that a transformation from petroleum-based transportation fuels to one heavily dependent on biofuels would be accompanied by significant changes in environmental impacts associated with the transportation sector. These changes may improve or degrade conditions relative to the current state. To enable choices that will make conditions better, this program carries out research to anticipate the nature and scale of the changes that may result in advance of large-scale deployment of biofuels.

Research Overview
The specific aims of this program are to develop and apply methods to study the life-cycle health, environmental, resource, and economic impacts and performance of the various pathways from biomass to fuel use. This program will produce a comprehensive framework for assessing both the benefits and impacts of biofuel technologies for environmental quality, human health, natural resources, and local, regional and global economies. This effort includes methods development, data collection, information management, and decision-support tools.

We are considering a range of likely biomass feedstocks and a portfolio of biofuels. During the first three years, we will focus our efforts on a) cane sugar + cellulose ethanol, b) corn starch + cellulose ethanol, c) corn starch + cellulose second-generation fuels (SGF), d) other cellulosic crops to produce ethanol, and e) other cellulosic crops to produce SGF. We also plan to devote some level of effort to address vegetable-oils-to-biodiesel and algal-oils-to-biodiesel pathways. In this summary, the term “biofuels” refers to these options.

Research Program
Our research program focuses on methods to study the life-cycle environmental, human health, and economic feasibility and performance of the various pathways from biomass to fuel use, including life-cycle assessment (LCA) techniques, life-cycle costing and economic analysis, and human health and ecological impact assessment. We are studying the air and water quality, land use, and human health and ecological impacts that arise from the life cycle of biofuels – from biomass growing through fuels production and distribution to fuels use in transportation (passenger and freight, on-road and off-road mobile sources, trains, ships, aircraft) and stationary (electricity generation, space heating) applications. We conduct this research in cooperation with the other EBI programs and projects that identify the biological, ecological, and technological alternatives for producing biofuels. We are currently addressing the following six research areas:

6) Economic analyse.

The integral relationships among these areas are illustrated in the figure below.

2009 Program Update:
The specific aim of this program is to develop and apply life-cycle assessment methods to understand the overall health, environmental, resource, and economic impacts and performance of the various pathways from biomass to fuels. The long-term goal of this effort is to enable the appropriate use of biofuels based on scientific insights, metrics, and tools to understand the conditions that make biofuels sustainable. During the last year we have developed much greater geographic resolution for exploring changes that arise from large-scale deployment of biofuels. We have applied this capacity to a case study for Illinois and Indiana, but with an eye on the entire United States. For the Illinois-Indiana case study, we have determined how the carbon-equivalent footprint and human health impacts change in a transition from existing petroleum refining to large-scale biofuel production. The EBI bioenergy analysts assisted our effort with an optimum series of biofuel production scenarios.

We have now compiled in a single framework the life-cycle external costs, carbon footprint, ecological damage, and human health burdens that accrue from each of the biofuel life stages: feedstock production, biofuel production, transportation and storage, and fuel use. We then allocated impacts to specific counties and aggregated them nationally to express impact per vehicle kilometer of travel or gasoline-liter equivalent. In the next steps, life-cycle impacts will be compared to a range of alternative fuels (such as petroleum gasoline, oil-sands gasoline, etc.) and the Illinois-Indiana case study will be expanded to the full U.S.

Life-Cycle Environmental and Economic Decision-Making for Alternative Biofuels