Acoustic Wave Enhanced Catalysis

Default ARPA-E Project Image

Program:
IDEAS
Award:
$425,000
Location:
Pasadena, California
Status:
ALUMNI
Project Term:
03/09/2015 - 09/30/2017
Website:

Technology Description:

The California Institute of Technology (Caltech) team is using first-principles reasoning (i.e. a mode of examination that begins with the most basic physical principles related to an issue and “builds up” from there) and advanced computational modeling to ascertain the underlying mechanisms that cause acoustic waves to affect catalytic reaction pathways. The team will first focus their efforts on two types of reactions for which there is strong experimental evidence that acoustic waves can enhance catalytic activity: Carbon Monoxide (CO) oxidation, and Ethanol decomposition. Armed with this new understanding, the team will suggest promising applications for acoustic wave enhanced catalysis to new reactions with large energy and emissions footprints, such as ammonia synthesis. As an ARPA-E IDEAS project, this research is at a very early stage. However, this novel approach to acoustic wave enhanced catalysis has the potential to improve energy and resource efficiency across broad swathes of the chemical, industrial, and other sectors of the economy.

Contact

ARPA-E Program Director:
Dr. Patrick McGrath
Project Contact:
William Goddard
Press and General Inquiries Email:
ARPA-E-Comms@hq.doe.gov
Project Contact Email:
wag@wag.caltech.edu

Related Projects

• Bigwood Systems - Global-Optimal Power Flow (G-OPF)
• California Institute of Technology (Caltech) - Nanomechanics of Electrodeposited Li
• California Institute of Technology (Caltech) - Acoustic Wave Enhanced Catalysis
• Citrine Informatics - Machine Learning for Solid Ion Conductors
• Colorado School of Mines - Thermoelectric Materials Discovery
• Colorado School of Mines - Ammonia Synthesis Membrane Reactor
• Columbia University - Integrated Power Adapter
• Columbia University - Computing Through Silicon Photonics
• Columbia University - Co-Generation of Fuels During Copper Bioleaching
• Cornell University - Secondary Lithium Metal Batteries
• Cree Fayetteville - Diamond Capacitors for Power Electronics
• Gas Technology Institute (GTI) - Methane Soft Oxidation
• GeneSiC Semiconductor - Novel Gallium Nitride Transistors
• George Washington University (GWU) - Transfer Printed Virtual Substrates
• Georgia Tech Research Corporation - Hollow Fibers for Separations
• Grid Logic - Nanostructured Core/Shell Powders for Magnets
• Harvard University - Transistor-less Power Supply Technology
• Harvard University - Mining the Deep Sea for Microbial Ethano- and Propanogenesis
• Hi Fidelity Genetics - Plant Root Phenotyping
• Inventev - Transmission-Based Power Generator
• Iowa State University (ISU) - Catalytic Autothermal Pyrolysis
• Johns Hopkins University - Adsorption Compression on Chemical Reactions
• Johns Hopkins University - Carbon Fiber from Methane
• Lawrence Berkeley National Laboratory (LBNL) - Metal-Supported SOFC for Vehicles
• New York University (NYU) - Grid Dynamics from City Light
• Northeastern University - Power Converter for Photovoltaic Applications
• Northeastern University - Materials for Magnetocaloric Applications
• Oregon State University (OSU) - Home Generator Benchmarking Program
• Otherlab - Visualizing Energy Data
• Palo Alto Research Center (PARC) - Large-Area Thermoelectric Generators
• Princeton Optronics - Development of a New Type of Laser Ignition System
• Princeton University - Acoustic Analysis for Battery Testing
• Purdue University - Bio-enabled Lightweight Metallic Structures
• Qromis - Reliable and Self-Clamped GaN Switch
• Ricardo - Reducing Automotive CAPEX Entry Barriers
• Rice University - Biological Ammonia Production
• Saint-Gobain Ceramics & Plastics - High Temperature Ceramics for Solar Fuel Production
• Sandia National Laboratories - High Gain Step-Up Converters
• Sandia National Laboratories - Power Conversion with Photoconductive Switches
• Signetron - Mobile Building Audits
• Space Orbital Services - Low Temperature Methane Conversion Through Impacting Common Alloy Catalysts
• Stanford University - CO2 for Commodity Polymer Synthesis
• Tandem PV - Unlock Perovskite Photovoltaics
• Tetramer Technologies - Enhanced Stability AEM at High Temperatures
• Texas Tech University - Solid-State Neutron Detectors
• United Technologies Research Center (UTRC) - High Performance Transportation Redox-Air Flow Cells
• United Technologies Research Center (UTRC) - Design of Ultra-Efficient Thermal-Fluid Components
• University of California, San Diego (UC San Diego) - Novel Electrolytes
• University of California, San Diego (UC San Diego) - Production of Large-Sized LOCH Parts
• University of Colorado, Boulder (CU-Boulder) - Capacitive Wireless Power System
• University of Maryland (UMD) - Current Collectors for Aqueous Batteries
• University of Maryland (UMD) - Next-Generation Air-Cooled Heat Exchangers
• University of Maryland (UMD) - High-Capacity Carbon Wires
• University of Maryland (UMD) - Electrochemical Compression for Ammonia
• University of Michigan - Benchtop Growth of High Quality Thin Film Photovoltaics
• University of Nebraska, Lincoln (UNL) - Electromagnetic Induction Power Converter
• University of Tennessee, Knoxville (UT) - Reversible Air Batteries
• University of Washington (UW) - Stable Magnetized Target Fusion Plasmas
• Utah State University (USU) - Feasibility Analysis of Electric Roadways

Release Date: