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Protonic ceramic membranes under asymmetric steam atmosphere | 54354
Journal of Chromatography & Separation Techniques

Journal of Chromatography & Separation Techniques
Open Access

ISSN: 2157-7064

+44 1300 500008

Protonic ceramic membranes under asymmetric steam atmosphere


2nd International Conference and Expo on Separation Techniques

September 26-28, 2016 Valencia, Spain

Sandrine Ricote, Anthony Manerbino and W Grover Coors

Colorado School of Mines, USA
Solid State Energy, USA
Protonetics, USA

Scientific Tracks Abstracts: J Chromatogr Sep Tech

Abstract :

A comprehensive analysis of proton transport in protonic ceramic membrane devices is presented. Thin, dense membranes of BaZr0.8Ce0.1Y0.1O3-d, BZCY81, may now be fabricated with relative ease at commercial scale. These devices have potential for supporting the emerging hydrogen economy and reducing dependence of fossil fuels. With protonic ceramic electrolytes it is possible to galvanically transport pure hydrogen from one side of a membrane to the other, making it possible to fabricate electrochemical devices and systems that were previously impractical or impossible. H2 can be produced from natural gas by steam reforming, whereby hydrogen may be extracted from a reacting stream of methane and steam in a protonic membrane reformer, PMR; Liquid hydrocarbons, such as ethylene and benzene, may be produced from dry methane in a catalytic membrane reactor by methane dehydroaromatization, MDA, with hydrogen extracted from the feed gas; Ammonia can be synthesized by pumping hydrogen through the membrane to react with nitrogen in a process called solid-state ammonia synthesis, SSAS; and H2 can be produced from water vapor by steam electrolysis in a protonic ceramic electrolysis cell (PCEC). In order for these devices to become commercially viable, a clear understanding of their operation in various use environments is necessary. All the devices listed above consume electric power to pump hydrogen across the membrane, which must be supplied by an external power source. The power consumed is the product of the applied voltage and the current consumed by the galvanic device, so it is important that the device have low resistance and high faradaic efficiency with respect to proton transport and that power is not wasted by parasitic losses. The proton current depends on the effective resistance, which depends on electrode performance, faradaic efficiency and bulk materials properties. Welldesigned electrodes can, in principle, be developed with low effective resistance, but in the final analysis it is the conductivity of the electrolyte membrane that limits the performance of these devices. The proton conductivity of BZCY81 is only a few millisiemens per centimeter in reducing atmosphere. More importantly, conductivity in BZCY is a strong function of water vapor pressure, making the electrolyte a mixed proton/steam conductor. This is an unusual characteristic that is unique to protonic ceramic electrolytes. The impact depends on the application. For example, MDA requires nominally dry methane on the feed side, while PMR requires moist atmosphere with steam-to-carbon ratio greater than unity. SSAS, on the other hand requires dry atmosphere on the permeate side, where nitrogen reacts with hydrogen to produce anhydrous ammonia. Steam electrolysis is carried out under moist oxidizing conditions on the feed side. In all cases, the desired permeate is hydrogen, as dry as possible to avoid the need for separation of hydrogen from steam, but as a practical matter, some steam will be present either due to steam permeation or added to the sweep gas intentionally. The transport properties of the membrane in each of these devices depend strongly on pH2O and pH2 on the feed and permeate sides. Knowledge of the electrolyte conductivity as a function of pH2O and pH2 on each side of the membrane is essential for designing cost-effective galvanic systems since this determines the protonic flux density.

Biography :

Sandrine Ricote has obtained her PhD on Ceramic Proton Conductors at the University of Burgundy, France. She has worked four years in the Department of Energy Conversion and Storage at the Danish Technical University as a Post-doc and then as a Scientist. In 2012, she moved to the Department of Mechanical Engineering at Colorado School of Mines. She is currently a Research Associate Professor with a main focus on ceramic proton conductors.

Email: sricote@mines.edu

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