Processing Ceramic Proton Conductor Membranes for Use in Steam Electrolysis

Leonard, Kwati; Deibert, Wendelin; Ivanova, Mariya; Meulenberg, Wilhelm Albert; Ishihara, Tatsumi; Matsumoto, Hiroshige

doi:10.3390/membranes10110339

Cited by 23 publications

(22 citation statements)

References 59 publications

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“…Both cells were fabricated using a well-established low-cost, sequential tape casting processing route. [52][53][54] Figure 7(a) presents typical open-circuit voltage (OCV) profiles obtained from both cells during the cathode reduction with varying H 2 concentrations. As observed, approximately four hours are sufficient to obtain OCV values (1.03 and 1.12 V, respectively), close to those calculated using the Nernst equation, thus verifying that both electrolyte layers are dense enough to ensure sufficient gas tightness.…”

Section: Steam Electrolysismentioning

confidence: 99%

Tailored and Improved Protonic Conductivity through Ba(Z_xCe_10−x)_0.08Y_0.2O_3−δ Ceramics Perovskites Type Oxides for Electrochemical Devices

et al. 2022

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Acceptor‐doped barium zirconate cerate electrolytes constitute prospective materials for highly efficient and environmentally friendly electrochemical devices. This manuscript employs a systematic approach to further optimize ionic conductivity in Ba(ZrxCe10−x)0.08Y0.2O3−δ, (1≤x≤9) oxides for moderate temperature electrolysis. We found two new composition variants by fixing a cerium/zirconium ratio of 5/4 at the perovskite B‐site with incremental zirconium, an observation that contrasts many reports suggesting a linear decrease in conductivity with increasing zirconium. As a result, the composition BaZr0.44Ce0.36Y0.2O3−δ demonstrates a superior ionic conductivity (10.1 mS cm−1 at 500 °C) to stability trade‐off whereas, BaZr0.16Ce0.64Y0.2O3−δ exhibits the highest conductivity (11.5 mS cm−1 at 500 °C) among the studied pellets. The high protonic conductivity is associated with a high degree of hydration, as confirmed by thermo‐gravimetric analysis. In addition, both compositions as electrolytes allow successful hydrogen production in a steam electrolyzer prototype. Electrolysis voltage as low as 1.3 V is attainable at current densities of 600 and 500 mA/cm2 respectively at 600 °C, achieving 82 % current efficiencies with the later electrolyte.

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Section: Steam Electrolysismentioning

confidence: 99%

Tailored and Improved Protonic Conductivity through Ba(Z_xCe_10−x)_0.08Y_0.2O_3−δ Ceramics Perovskites Type Oxides for Electrochemical Devices

et al. 2022

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“…In ref. 5 SrZr 0.5 -Ce 0.4 Y 0.1 O 3Àd is used in the anode substrate, which promotes the densication of the BZCY electrolyte layer by its high sintering shrinkage. However, one has to keep in mind that adding another material into the anode-electrolyte assembly increases the complexity of the system (e.g.…”

Section: Introductionmentioning

confidence: 99%

“…heating and power systems for houses, electric vehicles such as buses, or special cases as power supply for mobile electronic devices, 4 or for H 2 generation. 5 Interestingly, with adjusted catalytic activity at the anode side, a wide range of fuels such as ammonia and different hydrocarbons and alcohols can be used instead of hydrogen. 6 In recent years, PCFC performance has been impressively increased to more than 1.2 W cm À2 at 600 C by improving the processing of the electrolyte layer, choice of cathode materials, interface contacts through development of interlayers.…”

Section: Introductionmentioning

confidence: 99%

Fabrication of multi-layered structures for proton conducting ceramic cells

et al. 2022

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“…Although proton-conducting ceramics are still at the early stages of development, several research efforts have been made [143][144][145][146][147][148][149][150]. Overall, the process of hydrogen permeation through a dense proton conducting membrane involves several steps [122,151] where, S', BM, S" and G is the membrane surface at the inlet, the bulk membrane, the membrane surface at the outlet, and the gas, respectively.…”

Section: Ceramic Proton-conducting Membranesmentioning

confidence: 99%

“…Although proton-conducting ceramics are still at the early stages of development, several research efforts have been made [ 143 , 144 , 145 , 146 , 147 , 148 , 149 , 150 ]. Overall, the process of hydrogen permeation through a dense proton conducting membrane involves several steps [ 122 , 151 ]: H 2 gas diffusion to reaction sites on the surface of the feed side; H 2 adsorption, dissociation, and charge transfer at the membrane surface;

Proton reduction and hydrogen re-association at the membrane surface

where, S’ , BM , S” and G is the membrane surface at the inlet, the bulk membrane, the membrane surface at the outlet, and the gas, respectively.…”

Section: Hydrogen Separation/purification Technologiesmentioning

confidence: 99%

Recent Advances in Membrane-Based Electrochemical Hydrogen Separation: A Review

2021

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In this paper an overview of commercial hydrogen separation technologies is given. These technologies are discussed and compared—with a detailed discussion on membrane-based technologies. An emerging and promising novel hydrogen separation technology, namely, electrochemical hydrogen separation (EHS) is reviewed in detail. EHS has many advantages over conventional separation systems (e.g., it is not energy intensive, it is environmentally-friendly with near-zero pollutants, it is known for its silent operation, and, the greatest advantage, simultaneous compression and purification can be achieved in a one-step operation). Therefore, the focus of this review is to survey open literature and research conducted to date on EHS. Current technological advances in the field of EHS that have been made are highlighted. In the conclusion, literature gaps and aspects of electrochemical hydrogen separation, that require further research, are also highlighted. Currently, the cost factor, lack of adequate understanding of the degradation mechanisms related to this technology, and the fact that certain aspects of this technology are as yet unexplored (e.g., simultaneous hydrogen separation and compression) all hinder its widespread application. In future research, some attention could be given to the aforementioned factors and emerging technologies, such as ceramic proton conductors and solid acids.

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Processing Ceramic Proton Conductor Membranes for Use in Steam Electrolysis

Cited by 23 publications

References 59 publications

Tailored and Improved Protonic Conductivity through Ba(Z_xCe_10−x)_0.08Y_0.2O_3−δ Ceramics Perovskites Type Oxides for Electrochemical Devices

Tailored and Improved Protonic Conductivity through Ba(Z_xCe_10−x)_0.08Y_0.2O_3−δ Ceramics Perovskites Type Oxides for Electrochemical Devices

Fabrication of multi-layered structures for proton conducting ceramic cells

Recent Advances in Membrane-Based Electrochemical Hydrogen Separation: A Review

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Processing Ceramic Proton Conductor Membranes for Use in Steam Electrolysis

Cited by 23 publications

References 59 publications

Tailored and Improved Protonic Conductivity through Ba(ZxCe10−x)0.08Y0.2O3−δ Ceramics Perovskites Type Oxides for Electrochemical Devices

Tailored and Improved Protonic Conductivity through Ba(ZxCe10−x)0.08Y0.2O3−δ Ceramics Perovskites Type Oxides for Electrochemical Devices

Fabrication of multi-layered structures for proton conducting ceramic cells

Recent Advances in Membrane-Based Electrochemical Hydrogen Separation: A Review

Contact Info

Product

Resources

About

Tailored and Improved Protonic Conductivity through Ba(Z_xCe_10−x)_0.08Y_0.2O_3−δ Ceramics Perovskites Type Oxides for Electrochemical Devices

Tailored and Improved Protonic Conductivity through Ba(Z_xCe_10−x)_0.08Y_0.2O_3−δ Ceramics Perovskites Type Oxides for Electrochemical Devices