Analysis of the Past and Future Trends of Energy Use in Key Medium- and Large-Sized Chinese Steel Enterprises, 2000-2030. Lawrence Berkeley National Laboratory, 2013. LBNL-6380E..
Emerging Energy-efficiency and Carbon Dioxide Emissions-reduction Technologies for the Iron and Steel Industry. Berkeley: Lawrence Berkeley National Laboratory, 2013..
Energy-Efficiency Improvement Opportunities for the Textile Industry. Lawrence Berkeley National Laboratory, 2010..
"Barriers to energy efficiency improvement and decision-making behavior in Thai industry." Energy Efficiency 3.1 (2010) 33-52..
"Alternative Emerging Ironmaking Technologies for Energy-efficiency and Carbon Dioxide Emissions Reduction: A Technical Review." Renewable and Sustainable Energy Reviews 33 (2014) 645–658..
The State–of-the-Art Clean Technologies (SOACT) for Steelmaking Handbook (2nd Edition). Asia Pacific Partnership for Clean Development and Climate, 2010..
International Best Practices for Pre- Processing and Co-Processing Municipal Solid Waste and Sewage Sludge in the Cement Industry. Berkeley, CA: Lawrence Berkeley National Laboratory, 2012..
"Energy-Efficiency Technologies and Benchmarking the Energy Intensity for the Textile Industry." 2011 ACEEE Summer Study on Energy Efficiency in Industry 2011..
"Emerging Energy-Efficiency and CO2 Emissions-Reduction Technologies for Industry: A Review of Technologies for Alternative Ironmaking and Pulp and Paper Industry." 2013 ACEEE Summer Study on Energy Efficiency in Industry. 2013..
"Emerging Technologies for an Energy-Efficient, Water- Efficient, and Low- Pollution Textile Industry: A Technical Review." International Conference on Clean Energy 2014..
"Retrospective and prospective decomposition analysis of Chinese manufacturing energy use and policy implications." Energy Policy (2013)..
"The CO2 Abatement Cost Curve for the Thailand's Cement Industry." Journal of Cleaner Production 18.15 (2010) 1509-1518..
Assessment of Energy Efficiency Improvement and CO2 Emission Reduction Potentials in the Cement Industry in China. 2012. LBNL-5536E..
"Enabling a Rapid and Just Transition away from Coal in China." One Earth 3.2 (2020) 187 - 194..
"ELITE Cities: A low-carbon Eco-city Evaluation Tool for China." ECEEE 2013 Summer Study 2013..
"Is Your City Really Sustainable? A Tale of Jinan City Using Quantitative Low- Carbon Eco-city Tools." 2014 ACEEE Summer Study on Energy Efficiency in Building 2014: 119-130..
Rapid cost decrease of renewable energy and storage offers an opportunity to accelerate the decarbonization of China’s power system. 2020. LBNL-2001357..
"Rapid cost decrease of renewables and storage accelerates the decarbonization of China’s power system." Nature Communications 11.1 (2020)..
Estudio Preparatorio para la Implementación en Chile de Estándares Mínimos de Eficiencia Energética en Motores Industriales. Berkeley: LBNL, 2015. LBNL-187346..
Development of China's Energy-Efficiency Design Standard for Residential Buildings in the "Hot-Summer/Cold-Winter" Zone. City of Seattle;Natural Resources Defense Council; Lawrence Berkeley National Laboratory; China Academy of Building Research; Chongqing Architecture (Jianzu) University, 2001..
"Assessment of China's Renewable Energy Contribution During the 12th Five Year Plan." Energy Policy 62 (2013) 1533-1543..
"Updates to the China Design Standard for Energy Efficiency in Public Buildings." Energy Policy 87 (2015) 187-198. LBNL-1004493..
"A Fresh Look at Weather Impact on Peak Electricity Demand and Energy Use of Buildings Using 30-Year Actual Weather Data." Applied Energy 111 (2013) 333-350. LBNL-6280E..
"An Ontology to Represent Energy-Related Occupant Behavior in Buildings. Part II: Implementation of the DNAS framework using an XML schema." Building and Environment 94.1 (2015) 196-205. LBNL-1004501..
"Building Energy Benchmarking between the United States and China: Methods and Challenges." . 8th International Symposium on Heating, Ventilation and Air Conditioning 2014: 473-486..