What China can learn from international policy experiences to improve industrial energy efficiency and reduce CO2 emissions?. 2016. LBNL-1006470..
The State–of-the-Art Clean Technologies (SOACT) for Steelmaking Handbook (2nd Edition). Asia Pacific Partnership for Clean Development and Climate, 2010..
Retrospective and Prospective Decomposition Analysis of Chinese Manufacturing Energy Use, 1995-2020. Berkeley: Lawrence Berkeley National Laboratory, 2013. LBNL-6028E..
Quantifying the Co-benefits of Energy-Efficiency Programs: A Case Study of the Cement Industry in Shandong Province, China. Lawrence Berkeley National Laboratory, 2012..
National Level Co-Control Study of the Targets for Energy Intensity and Sulfur Dioxide in China. . Lawrence Berkerley National Laboratory, 2011. LBNL-5253E..
Motor Systems Efficiency Supply Curves. Vienna, Austria : the United Nations Industrial Development Organization, 2010..
Methodology for Estimating Purchased Prices of Energy-efficient Motors Internationally and Results for Selected Countries. 2015. LBNL-182927..
International Experience with Quantifying the Co-Benefits of Energy Efficiency and Greenhouse Gas Mitigation Programs and Policies. Lawrence Berkeley National Laboratory, 2012..
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..
Industrial Energy Audit Guidebook: Guidelines for Conducting an Energy Audit in Industrial Facilities. Lawrence Berkeley National Laboratory, 2010. LBNL-3991E..
Increasing Energy Efficiency and Reducing Emissions from China’s Cement Kilns: Audit Report of Two Cement Plants in Shandong Province, China. Lawrence Berkeley National Laboratory; E3M, Inc.; China Building Materials Academy, 2011..
Estudio Preparatorio para la Implementación en Chile de Estándares Mínimos de Eficiencia Energética en Motores Industriales. Berkeley: LBNL, 2015. LBNL-187346..
Energy-Efficiency Improvement Opportunities for the Textile Industry. Lawrence Berkeley National Laboratory, 2010..
Energy-Efficiency and Air-Pollutant Emissions-Reduction Opportunities for the Ammonia Industry in China. 2015. LBNL-183064..
Emerging Energy-Efficiency and Greenhouse Gas Mitigation Technologies for the Pulp and Paper Industry. Lawrence Berkeley National Laboratory, 2012..
Emerging Energy-efficiency and Carbon Dioxide Emissions-reduction Technologies for the Iron and Steel Industry. Berkeley: Lawrence Berkeley National Laboratory, 2013..
Emerging Energy Efficiency and Carbon Dioxide Emissions-Reduction Technologies for the Glass Industry. 2017..
Emerging Energy Efficiency and Carbon Dioxide Emissions-Reduction Technologies for Industrial Production of Aluminum. 2016. LBNL-1005789..
A Comparison of Iron and Steel Production Energy Use and Energy Intensity in China and the U.S. Lawrence Berkeley National Laboratory; Iron & Steel Research Institute, 2011. LBNL-4836E..
Comparison of Energy-Related Carbon Dioxide Emissions Intensity of the International Iron and Steel Industry: Case Studies from China, Germany, Mexico, and the United States. 2016. LBNL-1004069..
China Energy and Emissions Paths to 2030 (2nd Edition). . Lawrence Berkeley National Laboratory, 2012..
A Bottom-up Energy Efficiency Improvement Roadmap for China’s Iron and Steel Industry up to 2050. 2016. LBNL-1006356..
Assessment of Energy Efficiency Improvement in the United States Petroleum Refining Industry. Berkeley: Lawrence Berkeley National Laboratory, 2013. LBNL-6292E..
Assessment of Energy Efficiency Improvement and CO2 Emission Reduction Potentials in the Iron and Steel Industry in China. Berkeley: Lawrence Berkeley National Laboratory, 2012. LBNL-5535E..