Research Areas & Activities
Analysis Activities
2017
2016
2015
2014
2013
2012
2011
2010
2009
2008
2007
2006
2004
2003
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- 1. Introduction
- 1. Introduction
- 2. Project Results
- 2.1. Hydrogen Production, Distribution and Use
- 2.1.1. Introduction to Hydrogen Production, Distribution and Use
- 2.1.2. Engineering for the Direct Biological Conversion of Sunlight to Hydrogen
James R. Swartz, Alfred M. Spormann
- 2.1.3. Metabolic Engineering of Hydrogen Production in Cyanobacterial Heterocysts
Alfred M. Spormann, James R. Swartz
- 2.1.4. Development of a Molecular System for Efficient Production and Maturation of Fe-only Hydrogenases
Alfred M. Spormann, James R. Swartz
- 2.1.5. Nanoscale Electrochemical Probes for Monitoring Bioconversion Hydrogen
Fritz B. Prinz
- 2.1.6. Understanding, Predicting and Measuring Conductivity in Fuel Cell Electrolytes
Fritz B. Prinz
- 2.1.7. Nanoengineering of Hybrid Carbon Nanotube-Metal Nanocluster Composite Materials for Hydrogen Storage
Kyeongjae Cho, Bruce Clemens, Hongjie Dai, Anders Nilsson
- 2.1.8. Hydrogen Effects on Climate, Stratospheric Ozone, and Air Pollution
Mark Z. Jacobson, David M. Golden
- 2.1.9. Solid-State NMR Studies of Oxide Ion Conducting Ceramics for Enhanced Fuel Cell Performance
Jonathan F. Stebbins
- 2.1.10.
Modeling, Simulation and Characterization of Atomic Force Microscopy
Measurements for Ionic Transport and Impedence in PEM Fuel Cells
Peter M. Pinsky, David M. Barnett
- 2.2. Renewable Energy—Solar
- 2.2.1. Introduction to Renewable Energy—Solar
- 2.2.2. Nanostructured Photovoltaic Cells
Michael D. McGehee
- 2.2.3. Is Bioelectricity Possible (and Economically Feasible)?
Fritz B. Prinz
- 2.3. Renewable Energy—Biomass
- 2.3.1. Introduction to Renewable Energy—Biomass
- 2.3.2. Genetic Modification of Plant Cell Walls for Enhanced Biomass Production and Utilization
Chris Somerville
- 2.3.3. Directed Evolution and Genomic Analysis of Novel Yeast Species for More Efficient Biomass Conversion
Gavin Sherlock, R. Frank Rosenzweig
- 2.4. CO2 Storage
- 2.4.1. Introduction to CO2 Storage
- 2.4.2. Geologic CO2 Sequestration
Jerry M. Harris, Anthony R. Kovscek, Franklin M. Orr, Mark D. Zoback
- 2.4.3. A Numerical Simulation Framework for the Design, Management and Optimization of CO2 Sequestration in Subsurface Formations
Hamdi Tchelepi, Lou Durlofsky, Khalid Aziz
- 2.5. CO2 Capture and Separation
- 2.5.1. Introduction to CO2 Capture and Separation
- 2.5.2. Advanced Membrane Reactors in Energy Systems: A Carbon-Free Conversion of Fossil Fuels
Daniel Jansen and Joop Schoonman
- 2.6. Advanced Combustion
- 2.6.1. Introduction to Advanced Combustion
- 2.6.2. Controlled Combustion—An Approach for Reducing Irreversibilities in Energy Conversion
Craig T. Bowman
- 2.6.3. Development of Low-Irreversibility Engines
Christopher F. Edwards
- 2.6.4. Smart Sensors for Advanced Combustion Systems
Ronald K. Hanson
- 2.6.5. Characterization of Coal and Biomass Conversion Behaviors in Advanced Energy Systems
Reginald E. Mitchell
- 2.6.6. Process Informatics Model (PrIMe): A Systematic Approach to Building Combustion Chemistry Models
David M. Golden
- 2.7. Advanced Materials and Catalysts
- 2.7.1. Introduction to Advanced Materials and Catalysts
- 2.7.2. Efficient Interconversion of Chemical and Electrical Energy: Electrocatalysis with Discrete Transition Metal Complexes
Christopher Chidsey, Daniel Stack, Robert Waymouth
- 3. Analysis
- 3.1. Introduction to Analysis Activities
- 3.2. Energy Systems Analysis
A.J. Simon
- 3.3. Integrated Assessment of Energy Technologies
James Sweeney, John Weyant
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