Sulphate-ceria composite ceramics for energy environmental co-generation technology

被引：22

作者：

Liu, XR ^{[1
]}

Zhu, B

Xu, J

Sun, JC

Mao, ZQ

机构：

[1] Royal Inst Technol, Dept Chem Engn & Technol, S-10044 Stockholm, Sweden

[2] Goeta Technol Developer Int, S-17160 Solna, Sweden

[3] Norwegian Univ Sci & Technol, Dept Phys Chem, N-7491 Trondheim, Norway

[4] Dalian Maritime Univ, Inst Mat & Technol, Dalian 116026, Peoples R China

[5] Tsinghua Univ, Inst Nucl & New Energy Technol, China Assoc Hydrogen Energy, Beijing, Peoples R China

来源：

HIGH-PERFORMANCE CERAMICS III, PTS 1 AND 2 | 2005年 / 280-283卷

关键词：

samariurn doped ceria (SDC); Li2SO4; composite; O2- and H+ conduction; FC;

D O I：

10.4028/www.scientific.net/KEM.280-283.425

中图分类号：

TQ174 [陶瓷工业]; TB3 [工程材料学];

学科分类号：

0805 ; 080502 ;

摘要：

In this work ion conductivity and FC application were studied for the new type composite material based on SDC (samariurn doped ceria) and Li2SO4. Significant conductivity enhancement was achieved, e.g. 10(-2) - 0.4 Scm(-1) for the SDC-Li2SO4 compared to 10(-4) -10(-2) Scm(-1) for the SDC between 400 and 650degreesC. Some ion conductivity mechanisms were proposed correspondingly. Using the SDC-Li2SO4 composite materials as the electrolytes, we achieved high performances, 200-540 mWcm(-2). for intennediate temperature (450-650degreesC) solid oxide FC (ITSOFC) applications. Sulfates, typically Li2SO4, have an excellent chemical stability in sulfur containing atmosphere. The sulfate-ceria (SDC-Li2SO4) Composite materials can thus meet the demands to develop the sulfur tolerant and H2S FC technologies, which was also demonstrated successfully with significant importance for both fundamental and applied research.

引用

页码：425 / 430

页数：6

共 25 条

[11] Oxygen chemical potential and mixed conduction in doped ceria under influence of oxygen partial pressure gradient [J].

Mineshige, A ;

Yasui, T ;

Ohmura, N ;

Kobune, M ;

Fujii, S ;

Inaba, M ;

Ogumi, Z .

SOLID STATE IONICS, 2002, 152 :493-498

[12] PHYSICS OF INHOMOGENEOUS INORGANIC MATERIALS [J].

NAN, CW .

PROGRESS IN MATERIALS SCIENCE, 1993, 37 (01) :1-116

[13] Interfacial conduction in ionically conducting two-phase materials: Calculations using the grain consolidation model [J].

Nettelblad, B ;

Zhu, B ;

Mellander, BE .

PHYSICAL REVIEW B, 1997, 55 (10) :6232-6237

[14] A hydrogen sulfide fuel cell using a proton-conducting solid electrolyte [J].

Peterson, D ;

Winnick, J .

JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 1996, 143 (03) :L55-L56

[15] AN ELECTROCHEMICAL CLAUS PROCESS FOR SULFUR RECOVERY [J].

PUJARE, NU ;

TSAI, KJ ;

SAMMELLS, AF .

JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 1989, 136 (12) :3662-3678

[16] ENHANCED IONIC-CONDUCTION IN DISPERSED SOLID ELECTROLYTE SYSTEMS (DSES) AND OR MULTIPHASE SYSTEMS - AGL-AL2O3, AGL-SIO2, AGL-FLY ASH, AND AGL-AGBR [J].

SHAHI, K ;

WAGNER, JB .

JOURNAL OF SOLID STATE CHEMISTRY, 1982, 42 (02) :107-119

[17]

SUN JC, UNPUB PREPARATION CH

[18] CHEMICAL COGENERATION IN SOLID ELECTROLYTE CELLS - THE OXIDATION OF H2S TO SO2 [J].

YENTEKAKIS, IV ;

VAYENAS, CG .

JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 1989, 136 (04) :996-1002

[19] Functional ceria-salt-composite materials for advanced ITSOFC applications [J].

Zhu, B .

JOURNAL OF POWER SOURCES, 2003, 114 (01) :1-9

[20] Chemical stability study of Li2SO4 in a H2S/O2 fuel cell [J].

Zhu, B ;

Tao, SW .

SOLID STATE IONICS, 2000, 127 (1-2) :83-88

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