no |
title |
author |
magazine |
year |
volume |
issue |
page(s) |
type |
1 |
Advance fuel cells using Al2O3-nNaAlO2 composite as ion-conducting membrane
|
Wang, Baoyuan |
|
|
43 |
28 |
p. 12847-12855 |
article |
2 |
An experimental investigation on biogases production from Chinese herb residues based on dual circulating fluidized bed
|
Guan, Haibin |
|
|
43 |
28 |
p. 12618-12626 |
article |
3 |
Carbon-coated molybdenum carbide nanosheets derived from molybdenum disulfide for hydrogen evolution reaction
|
Huang, Yunjie |
|
|
43 |
28 |
p. 12610-12617 |
article |
4 |
Coking-resistant NbOx-Ni-Ce0.8Sm0.2O1.9 anode material for methanol-fueled solid oxide fuel cells
|
Yao, Xueli |
|
|
43 |
28 |
p. 12748-12755 |
article |
5 |
Editorial Board
|
|
|
|
43 |
28 |
p. iii-iv |
article |
6 |
Electrical properties of nanocube CeO2 in advanced solid oxide fuel cells
|
Li, Lingyao |
|
|
43 |
28 |
p. 12909-12916 |
article |
7 |
Electrochemical performance of a new structured low temperature SOFC with BZY electrolyte
|
Chen, Gang |
|
|
43 |
28 |
p. 12765-12772 |
article |
8 |
Electrochemical study of composite materials for coal-based direct carbon fuel cell
|
Ali, Amjad |
|
|
43 |
28 |
p. 12900-12908 |
article |
9 |
Electrodeposited Ni/CeO2 mulriple coating on SUS 430 steel interconnect
|
Li, Yandong |
|
|
43 |
28 |
p. 12811-12816 |
article |
10 |
Enhanced efficiency of hematite photoanode for water splitting with the doping of Ge
|
Zhao, Le |
|
|
43 |
28 |
p. 12646-12652 |
article |
11 |
7-ethylindole: A new efficient liquid organic hydrogen carrier with fast kinetics
|
Chen, Zhiwen |
|
|
43 |
28 |
p. 12688-12696 |
article |
12 |
Experimental and physical approaches on a novel semiconducting-ionic membrane fuel cell
|
Mi, Youquan |
|
|
43 |
28 |
p. 12756-12764 |
article |
13 |
Fabrication of integrated BZY electrolyte matrices for protonic ceramic membrane fuel cells by tape-casting and solid-state reactive sintering
|
Huang, Jianbing |
|
|
43 |
28 |
p. 12835-12846 |
article |
14 |
Heteroatom (B, N and P) doped porous graphene foams for efficient oxygen reduction reaction electrocatalysis
|
Dong, Fang |
|
|
43 |
28 |
p. 12661-12670 |
article |
15 |
High electrocatalytic performance of a graphene-supported PtAu nanoalloy for methanol oxidation
|
Chang, Gang |
|
|
43 |
28 |
p. 12803-12810 |
article |
16 |
High performance cathode-unsintered solid oxide fuel cell enhanced by porous Bi1.6Er0.4O3 (ESB) interlayer
|
Duan, Nanqi |
|
|
43 |
28 |
p. 12713-12719 |
article |
17 |
High performance ceramic nanocomposite fuel cells utilizing LiNiCuZn-oxide anode based on slurry method
|
Asghar, M.I. |
|
|
43 |
28 |
p. 12797-12802 |
article |
18 |
High-performance SOFC based on a novel semiconductor-ionic SrFeO3-δ–Ce0.8Sm0.2O2-δ membrane
|
Meng, Yuanjing |
|
|
43 |
28 |
p. 12697-12704 |
article |
19 |
Hydrogen and LNG production from coke oven gas with multi-stage helium expansion refrigeration
|
Xu, Jingxuan |
|
|
43 |
28 |
p. 12680-12687 |
article |
20 |
Improvement in stability of PtRu electrocatalyst by carbonization of in-situ polymerized polyaniline
|
Zhang, Quan |
|
|
43 |
28 |
p. 12730-12738 |
article |
21 |
New developments in fuel cells: From traditional to innovative concepts (Preface for China-Europe forum for advanced fuel cell and new energy)
|
Zhu, Bin |
|
|
43 |
28 |
p. 12595 |
article |
22 |
On dynamic operation modes of fuel cell: A comparison between the single-loop and multi-loop controls
|
Fu, Hao |
|
|
43 |
28 |
p. 12856-12869 |
article |
23 |
Plasma sprayed coatings for low-temperature SOFC and high temperature effects on Lix(Ni,Co)yO2 catalyst layers
|
Yuan, Kang |
|
|
43 |
28 |
p. 12782-12788 |
article |
24 |
Preparation and properties of PrBa0.5Sr0.5Co1.5Fe0.5O5+δ as novel oxygen electrode for reversible solid oxide electrochemical cell
|
Tian, Yunfeng |
|
|
43 |
28 |
p. 12603-12609 |
article |
25 |
Readily fabricated NiCo alloy-metal oxide-carbon black hybrid catalysts for the oxygen reduction reactions in the alkaline media
|
Li, Fengjiao |
|
|
43 |
28 |
p. 12637-12645 |
article |
26 |
Remarkable ionic conductivity and catalytic activity in ceramic nanocomposite fuel cells
|
Asghar, M.I. |
|
|
43 |
28 |
p. 12892-12899 |
article |
27 |
Rod-like nonstoichiometric Ni0.85Se as efficient electrocatalysts for hydrogen evolution reaction
|
Zhao, Wenjun |
|
|
43 |
28 |
p. 12653-12660 |
article |
28 |
Semiconductor electrolyte for low-operating-temperature solid oxide fuel cell: Li-doped ZnO
|
Xia, Chen |
|
|
43 |
28 |
p. 12825-12834 |
article |
29 |
Single-phase electronic-ionic conducting Sm3+/Pr3+/Nd3+ triple-doped ceria for new generation fuel cell technology
|
Liu, Yanyan |
|
|
43 |
28 |
p. 12817-12824 |
article |
30 |
Solid oxide fuel cell technology for sustainable development in China: An over-view
|
Lu, Yuzheng |
|
|
43 |
28 |
p. 12870-12891 |
article |
31 |
Study on charge transportation in the layer-structured oxide composite of SOFCs
|
Liu, Xueqi |
|
|
43 |
28 |
p. 12773-12781 |
article |
32 |
The composite electrolyte with an insulation Sm2O3 and semiconductor NiO for advanced fuel cells
|
Liu, Liang |
|
|
43 |
28 |
p. 12739-12747 |
article |
33 |
The heterogeneous electrolyte of CuFeO2 nano-flakes composited with flower-shaped ZnO for advanced solid oxide fuel cells
|
Zhang, Jing |
|
|
43 |
28 |
p. 12789-12796 |
article |
34 |
The investigation of Ag & LaCo0.6Ni0.4O3−δ composites as cathode contact material for intermediate temperature solid oxide fuel cells
|
Yang, Jiajun |
|
|
43 |
28 |
p. 12705-12712 |
article |
35 |
The structure and magnetic properties of magnesium-substituted LaFeO3 perovskite negative electrode material by citrate sol-gel
|
Lin, Qing |
|
|
43 |
28 |
p. 12720-12729 |
article |
36 |
The synthesis of ZnO/SrTiO3 composite for high-efficiency photocatalytic hydrogen and electricity conversion
|
Wu, Yan |
|
|
43 |
28 |
p. 12627-12636 |
article |
37 |
Three dimension (3D) hierarchical electrode (Au/rGO/CoPt3) for electrooxidation of ethanol in fuel cells
|
Huang, Kang |
|
|
43 |
28 |
p. 12596-12602 |
article |
38 |
Vapor-liquid equilibria for low temperature CH4/H2 mixture
|
Lin, Wensheng |
|
|
43 |
28 |
p. 12671-12679 |
article |