Electrochemical Separation, Pumping, and Storage of Hydrogen or Oxygen into Nanocapillaries Via High Pressure MEA Seals

Electrochemical Separation, Pumping, and Storage of Hydrogen or Oxygen into Nanocapillaries Via High Pressure MEA Seals

High-density storage of gases remains a major technological hurdle for many fields. The U.S. Department of Energy (DOE), for example, reduced their hydrogen storage targets for automotive applications due to the inability of technologies to reach the system-level targets. Without significant improve...

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Bibliographische Detailangaben
Hauptverfasser: Reeves, Ryan D, Schwartz, Nicholas R, Chester, Gregory E, Diez, Douglas S, Solomon, Mitchell L, Cox, Phillip, Hill, Justin J
Format: Report
Sprache:eng
Schlagworte:
ABSORBERS(MATERIALS)
ANODIC COATINGS
BRIEFING CHARTS
CAPACITY(QUANTITY)
CAPILLARITY
CARBON NANOTUBES
CATALYSTS
Electrochemical Energy Storage
ELECTROCHEMICAL GAS COMPRESSION
ELECTROCHEMICAL SELF-ASSEMBLY
ELECTROCHEMISTRY
ELECTRODES
FABRICATION
FUELS
GAS COMPRESSORS
GAS CYLINDERS
GAS PUMPS
GRAVIMETRY
HIGH DENSITY
HIGH PRESSURE
HYDROGEN
HYDROGEN STORAGE
ION EXCHANGE
MEA(MEMBRANE ELECTRODE ASSEMBLY)
MEMBRANES
Miscellaneous Materials
NANOCAPILLARIES
NANOMATERIALS
NANOPARTICLES
OXYGEN STORAGE
PRESSURIZATION
Pumps, Filters, Pipes, Tubing, Fittings & Vlvs
SELF ASSEMBLED MONOLAYERS
SEPARATION
STORAGE
TEMPLATES
TRANSPORTATION
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Beschreibung
Zusammenfassung:High-density storage of gases remains a major technological hurdle for many fields. The U.S. Department of Energy (DOE), for example, reduced their hydrogen storage targets for automotive applications due to the inability of technologies to reach the system-level targets. Without significant improvements in hydrogen storage density, hydrogen as a transportation fuel remains unfeasible. In other fields, the low volumetric and gravimetric storage densities of oxygen gas cylinders can be cumbersome or prohibitively expensive for applications like terrestrial and marine breathing apparatus or manned space exploration. Emerging technologies, such as sorbents and chemical complexes, show potential for gas storage. However, the ability to achieve application-specific gas delivery rates and high storage densities, while operating reversibly at ambient temperature, remains elusive. In contrast, it may be possible to achieve high gas storage densities and potentially high gas delivery rates using nanocapillaries when used in conjunction with a membrane electrode assembly (MEA). Hoop stress calculations show that the pressure tolerances of cylinders are inversely proportional to the radius. Indeed, glass microcapillaries have already theoretically and experimentally demonstrated the capacity to achieve DOE hydrogen storage targets at a materials-level. This technology can be further improved by reducing the capillary radius to the nanoscale; however, the capping and pressurization of the gas in micro- or nanocapillaries remains problematic. Presented here is the fabrication of nanocapillary arrays capped by an MEA for highly reversible storage of gases with the potential for high rate pumping and high-density storage. Very high aspect ratio and densely packed nanocapillary arrays are produced through aluminum anodization. Presented at the 228th ECS Meeting, held in Phoenix, AZ, 14 October 2014. CA: Air Force Test Center Edwards AFB CA CC: 012100