Protonic Ceramic Electrochemical Cell for Efficient Separation of Hydrogen

Tong, Yongcheng; Meng, Xie; Luo, Ting; Cui, Changsong; Wang, Yue; Wang, Shiwei; Peng, Ranran; Xie, Bin; Chen, Chusheng; Zhan, Zhongliang

doi:10.1021/acsami.0c04024

Cited by 17 publications

(13 citation statements)

References 33 publications

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“…As depicted in Figure 9 d, at least three processes can be identified to occur at a certain temperature, labeled P1, P2, and P3. On the basis of NiO-BCZY reduction temperature and the evaluation of activation energies corresponding to the DRT peaks reported in ref ( 15 ), P1 is associated with the charge transfer reaction between Ni and the BCZY interface, P2 is related to the formation of nickel-H solutions (α-phase), and P3, which is slightly visible at 350 °C, is related to the hydrogen adsorption and desorption processes on the nickel surface. From an estimate of the time constant for each peak P1 at 350, 400, and 450 °C, charge transfer is determined to occur at approximately 200, 140, and 70 kHz.…”

Section: Resultsmentioning

confidence: 96%

“… Despite the simplicity of its nature, the development of such a P-SOC has been slow or limited to lab-scale prototypes (effective surface area <1 cm 2 ) 15 due to various challenges, notably including large area defect-free membrane processing, the requirement for high sintering temperatures, chemo-thermomechanical compatibility with the components, and the necessity for gastight sealing and interconnection components to upscale to a stack level. 15 , 20 − 22 Importantly, the key parameters that govern the performance of a P-SOC pump are the conductivity, thickness, and gas-tightness of the membrane, while other parameters are kept constant (e.g., temperature, partial pressure of hydrogen, etc.).…”

Section: Introductionmentioning

confidence: 99%

“…This calls for the separation of pure hydrogen from the product gases of SMR, which can be realized via a number of technologies, such as pressure swing adsorption − or through the use of a galvanic hydrogen pump employing a perovskite based protonic ceramic membrane. − For the former techniques, hydrogen permeation occurs under a high pressure gradient across a selective metal-based membrane (usually composed of palladium or its alloys with a thickness of 10–15 μm) or molecular sieves . Although an established hydrogen purification technology operates well at large scales with a high pressure gradient (5–20 bar) across the membrane, it is capital and energy intensive.…”

Section: Introductionmentioning

confidence: 99%

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Development of Electrode-Supported Proton Conducting Solid Oxide Cells and their Evaluation as Electrochemical Hydrogen Pumps

Mushtaq

Welzel

Sharma

et al. 2022

ACS Appl. Mater. Interfaces

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Protonic ceramic solid oxide cells (P-SOCs) have gained widespread attention due to their potential for operation in the temperature range of 300–500 °C, which is not only beneficial in terms of material stability but also offers unique possibilities from a thermodynamic point of view to realize a series of reactions. For instance, they are ideal for the production of synthetic fuels by hydrogenation of carbon dioxide and nitrogen, upgradation of hydrocarbons, or dehydrogenation reactions. However, the development of P-SOC is quite challenging because it requires a multifront optimization in terms of material synthesis and fabrication procedures. Herein, we report in detail a method to overcome various fabrication challenges for the development of efficient and robust electrode-supported P-SOCs (Ni-BCZY/BCZY/Ni-BCZY) based on a BaCe 0.2 Zr 0.7 Y 0.1 O 3−δ (BCZY271) electrolyte. We examined the effect of pore formers on the porosity of the Ni-BCZY support electrode, various electrolyte deposition techniques (spray, spin, and vacuum-assisted), and thermal treatments for developing robust and flat half-cells. Half-cells containing a thin (10–12 μm) pinhole-free electrolyte layer were completed by a screen-printed Ni-BCZY electrode and evaluated as an electrochemical hydrogen pump to access the functionality. The P-SOCs are found to show a current density ranging from 150 to 525 mA cm –2 at 1 V over an operating temperature range of 350–450 °C. The faradaic efficiency of the P-SOCs as well as their stability were also evaluated.

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Section: Resultsmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Development of Electrode-Supported Proton Conducting Solid Oxide Cells and their Evaluation as Electrochemical Hydrogen Pumps

Mushtaq

Welzel

Sharma

et al. 2022

ACS Appl. Mater. Interfaces

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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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An effective strategy to boost hydrogen separation performance through stable mixed proton‐electron conducting membrane

Luo,

Wang,

et al. 2023

AIChE Journal

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Hydrogen separation and purification are key to widespread application of hydrogen energy. Hydrogen permeable membranes based on lanthanum tungstate (LWO) attract attention due to favorable mechanical strength and chemical stability. However, industrial application of LWO‐based membranes has remained challenging because of modest hydrogen permeances. Here we report a novel graded porous supported symmetric (GPSS) LWO‐based membrane with improved transport properties, gas exchange dynamics, and operational stability, boosting stable hydrogen flux by several times over previously reported state‐of‐the‐art membranes.

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Protonic Ceramic Electrochemical Cell for Efficient Separation of Hydrogen

Cited by 17 publications

References 33 publications

Development of Electrode-Supported Proton Conducting Solid Oxide Cells and their Evaluation as Electrochemical Hydrogen Pumps

Development of Electrode-Supported Proton Conducting Solid Oxide Cells and their Evaluation as Electrochemical Hydrogen Pumps

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

An effective strategy to boost hydrogen separation performance through stable mixed proton‐electron conducting membrane

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