China Energy and Emissions Paths to 2030 (2nd Edition). Lawrence Berkeley National Laboratory, 2012.
Biomass Allocation Model – Comparing Alternative Uses of Scarce Biomass Energy Resource Through Estimations of Future Biomass Use for Liquid Fuels and Electricity., 2008.
Assessment of Energy Efficiency Improvement in the United States Petroleum Refining Industry. Berkeley: Lawrence Berkeley National Laboratory, 2013.
Assessment of Energy Efficiency Improvement and CO2 Emission Reduction Potentials in the Cement Industry in China., 2012.
Assessment of Energy Efficiency Improvement and CO2 Emission Reduction Potentials in the Iron and Steel Industry in China. Berkeley: Lawrence Berkeley National Laboratory, 2012.
The Technology Path to Deep Greenhouse Gas Emissions Cuts by 2050: The Pivotal Role of Electricity." Science 335, no. 6064 (2012): 53-59."
Technologies and policies to decarbonize global industry: Review and assessment of mitigation drivers through 2070." Applied Energy 266 (2020): 114848."
National-level infrastructure and economic effects of switchgrass co-firing with coal in existing power-plants for carbon mitigation. Environmental Science and Technology." Environmental Science & Technology 42, no. 10 (2008): 3501-3507."
Inclining for the Climate: GHG Reduction via Residential Electricity Ratemaking." Public Utilities Fortnightly 147, no. 5 (2009): 40-45."
Fuzzy GIS-based multi-criteria evaluation for U.S. Agave production as a bioenergy feedstock." Global Change Biology – Bioenergy (2014)."
Feedstock loss from drought is a major economic risk for biofuel producers." Biomass and Bioenergy 69 (2014): 135-143."
Energy Efficiency Improvements Potential in the U.S. Petroleum Refining Industry In 2014 ECEEE Summer Study on Energy Efficiency in Industry. Arnhem, the Netherlands: The European Council for an Energy Efficient Economy, 2014.
Key Factors Influencing Autonomous Vehicles’ Energy and Environmental Outcome." In Road Vehicle Automation, 127-135. , 2014."