All Stories

  1. semiconductors and their heterostructure composites used for energy devices
  2. Nanotechnology Based Green Energy Conversion Devices with Multifunctional Materials at Low Temperatures
  3. Novel fuel cell with nanocomposite functional layer designed by perovskite solar cell principle
  4. Natural Hematite for Next-Generation Solid Oxide Fuel Cells
  5. Synthesis of Ba0.3Ca0.7Co0.8Fe0.2O3-δ composite material as novel catalytic cathode for ceria-carbonate electrolyte fuel cells
  6. Flowerlike CeO2 microspheres coated with Sr2Fe1.5Mo0.5Ox nanoparticles for an advanced fuel cell
  7. Electrochemical study of lithiated transition metal oxide composite for single layer fuel cell
  8. Scaled up low-temperature SOFCs with symmetrical electrode for applications
  9. Significant enhancement of UV emission in ZnO nanorods subject to Ga+ ion beam irradiation
  10. Effects of composition on the electrochemical property and cell performance of single layer fuel cell
  11. Schottky Junction Effect on High Performance Fuel Cells Based on Nanocomposite Materials
  12. Significance enhancement in the conductivity of core shell nanocomposite electrolytes
  13. Microstructure and catalytic activity of Li0.15Ni0.25Cu0.3Zn0.3O2−δ-Ce0.8Sm0.2O1.9-carbonate nanocomposite materials functioning as single component fuel cell
  14. Ceria-carbonate composite for low temperature solid oxide fuel cell: Sintering aid and composite effect
  15. Time-dependent performance change of single layer fuel cell with Li0.4Mg0.3Zn0.3O/Ce0.8Sm0.2O2−δ composite
  16. A commercial lithium battery LiMn-oxide for fuel cell applications
  17. Fabrication of electrolyte-free fuel cell with Mg0.4Zn0.6O/Ce0.8Sm0.2O2−δ–Li0.3Ni0.6Cu0.07Sr0.03O2−δ layer
  18. Ce0.8(SmZr)0.2O2-carbonate nanocomposite electrolyte for solid oxide fuel cell
  19. Semiconductor LiNiCuZnOx and ionic GDC composite for one layer fuel cell
  20. Preface
  21. An improved synthesis method of ceria-carbonate based composite electrolytes for low-temperature SOFC fuel cells
  22. A new energy conversion technology based on nano-redox and nano-device processes
  23. Recent development of ceria-based (nano)composite materials for low temperature ceramic fuel cells and electrolyte-free fuel cells
  24. Breakthrough fuel cell technology using ceria-based multi-functional nanocomposites
  25. Studies of modified lithiated NiO cathode for low temperature solid oxide fuel cell with ceria-carbonate composite electrolyte
  26. Direct lignin fuel cell for power generation
  27. Editorial
  28. Editorial
  29. Nanocomposite electrode materials for low temperature solid oxide fuel cells using the ceria-carbonate composite electrolytes
  30. Enhanced ionic conductivity in calcium doped ceria – Carbonate electrolyte: A composite effect
  31. State of the art ceria-carbonate composites (3C) electrolyte for advanced low temperature ceramic fuel cells (LTCFCs)
  32. Pr2NiO4–Ag composite cathode for low temperature solid oxide fuel cells with ceria-carbonate composite electrolyte
  33. Design of a 5‐kW advanced fuel cell polygeneration system
  34. Fuel Cell and Electrolysis Studies with Dual Phase Proton and Oxide Ion Conduction
  35. Low temperature ceramic fuel cells using all nano composite materials
  36. Study of CuNiZnGdCe-Nanocomposite Anode for Low Temperature SOFC
  37. Electrochemical study on co-doped ceria–carbonate composite electrolyte
  38. A novel core–shell nanocomposite electrolyte for low temperature fuel cells
  39. Pressurization effect on dry reforming of biogas in kilohertz spark-discharge plasma
  40. Advanced electrolyte-free fuel cells based on functional nanocomposites of a single porous component: analysis, modeling and validation
  41. Single-component fuel cells fabricated by spark plasma sintering
  42. Nanocomposites for Advanced Fuel Cell Technology
  43. Advanced Multi‐Fuelled Solid Oxide Fuel Cells (ASOFCs) Using Functional Nanocomposites for Polygeneration
  44. Thermodynamic analysis of ITSOFC co-generation system fueled by ethanol
  45. Advanced fuel cells: from materials and technologies to applications
  46. Single-component and three-component fuel cells
  47. A single-component fuel cell reactor
  48. An Electrolyte‐Free Fuel Cell Constructed from One Homogenous Layer with Mixed Conductivity
  49. A fuel cell with a single component functioning simultaneously as the electrodes and electrolyte
  50. Ceria-based nanocomposite with simultaneous proton and oxygen ion conductivity for low-temperature solid oxide fuel cells
  51. Fuel cells need the electrolyte?
  52. Zn[sub 0.6]Fe[sub 0.1]Cu[sub 0.3]/GDC Composite Anode for Solid Oxide Fuel Cell
  53. GDC-Y[sub 2]O[sub 3] Oxide Based Two Phase Nanocomposite Electrolyte
  54. Characterization and Development of Bio-Ethanol Solid Oxide Fuel Cell
  55. Preparation and Characterization of Nanocomposite Calcium Doped Ceria Electrolyte With Alkali Carbonates (NK-CDC) for SOFC
  56. A nanostructure anode (Cu0.2Zn0.8) for low-temperature solid oxide fuel cell at 400–600°C
  57. Functional ceria-salt-composite materials for advanced ITSOFC applications
  58. Study on calcium and samarium co-doped ceria based nanocomposite electrolytes
  59. Samarium doped ceria–(Li/Na)2CO3 composite electrolyte and its electrochemical properties in low temperature solid oxide fuel cell
  60. Samarium‐Doped Ceria Nanowires: Novel Synthesis and Application in Low‐Temperature Solid Oxide Fuel Cells
  61. Thermal stability study of SDC/Na2CO3 nanocomposite electrolyte for low-temperature SOFCs
  62. Improved ceria–carbonate composite electrolytes
  63. Special IJHE issue from HyForum 2008 conference
  64. Thermodynamic analysis of ITSOFC hybrid system for polygenerations
  65. Carbon anode in direct carbon fuel cell
  66. SDC–LiNa carbonate composite and nanocomposite electrolytes
  67. GDC-Y
  68. Preparation and Characterization of Nanocomposite Calcium Doped Ceria Electrolyte With Alkali Carbonates (NK-CDC) for SOFC
  69. Solid oxide fuel cell (SOFC) technical challenges and solutions from nano-aspects
  70. Enhancement of Conductivity in Ceria-Carbonate Nanocomposites for LTSOFCs
  71. Solid oxide fuel cell (SOFC) using industrial grade mixed rare-earth oxide electrolytes
  72. Structural Studies on Ceria-Carbonate Composite Electrolytes
  73. Structural Studies on Ceria-Carbonate Composite Electrolytes
  74. Fuel Cell Studies Using the CeO2-La2O3 Based Electrolytes
  75. Sulphate-Ceria Composite Ceramics for Energy Environmental Co-Generation Technology
  76. Advanced Hybrid Ion Conducting Ceramic Composites and Applications in New Fuel Cell Generation
  77. Carbon doped MO–SDC material as an SOFC anode
  78. Novel AC-MO-CSC Anode for Direct Methanol Low Temperature Ceramic Fuel Cells
  79. Development of Low Temperature Solid Oxide Fuel Cells
  80. Preparation and Characterization of Pt/Superfine Mesocarbon Microbead Powers Electrocatalysts
  81. Compatible Cathode Materials for High Performance Low Temperature (300–600°C) Solid Oxide Fuel Cells
  82. Advanced Hybrid Ion Conducting Ceramic Composites and Applications in New Fuel Cell Generation
  83. Fluoride-based electrolytes and their applications for intermediate temperature ceramic fuel cells
  84. Sulphate-Ceria Composite Ceramics for Energy Environmental Co-Generation Technology
  85. Direct Preparation of Ce
  86. Novel AC-M-SCC Anode Materials for Solid Oxide Fuel Cells Using Methanol at Intermediate or Low Temperature
  87. Novel hybrid conductors based on doped ceria and BCY20 for ITSOFC applications
  88. Advanced Ceramic Fuel Cell R&D
  89. Modeling and Analysis of a Bio-Fuelled Ceramic Fuel Cell Stack
  90. Calcium doped ceria-based materials for cost-effective intermediate temperature solid oxide fuel cells
  91. Functional ceria–salt-composite materials for advanced ITSOFC applications
  92. Doped ceria–chloride composite electrolyte for intermediate temperature ceramic membrane fuel cells
  93. Innovative solid carbonate-ceria composite electrolyte fuel cells
  94. Proton and oxygen ion-mixed-conducting ceramic composites and fuel cells
  95. INTERMEDIATE TEMPERATURE SOLID OXIDE FUEL CELLS USING CERIA-BASED COMPOSITE ELECTROLYTES
  96. LiF–CaH2 alumina electrolytes for intermediate temperature fuel cell applications
  97. Proton and oxygen ion conduction in nonoxide ceramics
  98. New advanced ceramic fuel cell technology using MFx (M=Na, Ca, Ba, La, x=1–3) based electrolytes
  99. Intermediate temperature proton conducting salt–oxide composites
  100. Natural salt and fluoride based electrolytes fuel cells
  101. Characterisation of MF–BaF2–CaH2–Al2O3 (M=Li, Na) hydrofluorides based on fuel cell studies
  102. Transparent conducting CeO2–SiO2 thin films
  103. Using a fuel cell to study fluoride-based electrolytes
  104. Impedance spectroscopy study of gadolinia-doped ceria
  105. Non-conventional fuel cell systems: new concepts and development
  106. Fast ionic conducting film ceramic membranes with advanced applications
  107. Advanced environmental/ energy technology
  108. Status and future prospects of intermediate, high temperature proton conductor fuel cell
  109. Electrical properties and proton conduction of gadolinium doped ceria
  110. Determination of proton diffusion in solid electrolytes
  111. fProton conduction and diffusion in Li2SO4
  112. Non-conventional solid state fuel cells: Materials & technology
  113. Proton conducting composite materials at intermediate temperatures
  114. Intermediate temperature fuel cells with electrolytes based on oxyacid salts
  115. Infrared spectra of the rubidium nitrate alumina composites
  116. Cubic rubidium nitrate at room temperature
  117. Ionic Conduction in Composite Materials Containing One Molten Phase
  118. Cubic alkali orthophosphates with high ionic conductivity
  119. ESR spectra on montmorillonites