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CONTENTS

  1. AAAA battery
  2. AAA battery
  3. AA battery
  4. A battery
  5. Absorbent glass mat
  6. Alessandro Volta
  7. Alkaline battery
  8. Alkaline fuel cell
  9. Aluminium battery
  10. Ampere
  11. Atomic battery
  12. Backup battery
  13. Baghdad Battery
  14. Batteries
  15. Battery charger
  16. B battery
  17. Bernard S. Baker
  18. Beta-alumina solid electrolyte
  19. Betavoltaics
  20. Bio-nano generator
  21. Blue energy
  22. Bunsen cell
  23. Car battery
  24. C battery
  25. Clark cell
  26. Concentration cell
  27. Coulomb
  28. 2CR5
  29. Daniell cell
  30. Direct borohydride fuel cell
  31. Direct-ethanol fuel cell
  32. Direct methanol fuel cell
  33. Dry cell
  34. Dry pile
  35. Duracell
  36. Duracell Bunny
  37. Earth battery
  38. Electric charge
  39. Electric current
  40. Electricity
  41. Electrochemical cell
  42. Electrochemical potential
  43. Electro-galvanic fuel cell
  44. Electrolysis
  45. Electrolyte
  46. Electrolytic cell
  47. Electromagnetism
  48. Electromotive force
  49. Energizer Bunny
  50. Energy
  51. Energy density
  52. Energy storage
  53. Flashlight
  54. Float charging
  55. Flow Battery
  56. Formic acid fuel cell
  57. Fuel cell
  58. Fuel cell bus trial
  59. Galvanic cell
  60. Gel battery
  61. Grove cell
  62. Half cell
  63. History of the battery
  64. Hybrid vehicle
  65. Lead-acid battery
  66. Leclanchι cell
  67. Lemon battery
  68. List of battery sizes
  69. List of battery types
  70. List of fuel cell vehicles
  71. Lithium battery
  72. Lithium ion batteries
  73. Lithium iron phosphate battery
  74. Lithium polymer cell
  75. LR44 battery
  76. Luigi Galvani
  77. Manganese dioxide
  78. Memory effect
  79. Mercury battery
  80. Metal hydride fuel cell
  81. Methane reformer
  82. Methanol reformer
  83. Michael Faraday
  84. Microbial fuel cell
  85. Molten carbonate fuel cell
  86. Molten salt battery
  87. Nickel-cadmium battery
  88. Nickel-iron battery
  89. Nickel metal hydride
  90. Nickel-zinc battery
  91. Open-circuit voltage
  92. Optoelectric nuclear battery
  93. Organic radical battery
  94. Oxyride battery
  95. Panasonic EV Energy Co
  96. Peukert's law
  97. Phosphoric acid fuel cell
  98. Photoelectrochemical cell
  99. Polymer-based battery
  100. Power density
  101. Power management
  102. Power outage
  103. PP3 battery
  104. Primary cell
  105. Prius
  106. Proton exchange membrane
  107. Proton exchange membrane fuel cell
  108. Protonic ceramic fuel cell
  109. Radioisotope piezoelectric generator
  110. Ragone chart
  111. RCR-V3
  112. Rechargeable alkaline battery
  113. Reverse charging
  114. Reversible fuel cell
  115. Searchlight
  116. Secondary cell
  117. Short circuit
  118. Silver-oxide battery
  119. Smart Battery Data
  120. Smart battery system
  121. Sodium-sulfur battery
  122. Solid oxide fuel cell
  123. Super iron battery
  124. Thermionic converter
  125. Trickle charging
  126. Vanadium redox battery
  127. Volt
  128. Voltage
  129. Voltaic pile
  130. Watch battery
  131. Water-activated battery
  132. Weston cell
  133. Wet cell
  134. Zinc-air battery
  135. Zinc-bromine flow battery
  136. Zinc-carbon battery
 



BATTERIES
This article is from:
http://en.wikipedia.org/wiki/Alkaline_fuel_cell

All text is available under the terms of the GNU Free Documentation License: http://en.wikipedia.org/wiki/Wikipedia:Text_of_the_GNU_Free_Documentation_License

Alkaline fuel cell

From Wikipedia, the free encyclopedia

 
Diagram of an Alkaline Fuel Cell. 1: Hydrogen 2:Electron flow 3:Charge 4:Oxygen 5:Cathode 6:Electrolyte 7:Anode 8:Water 9:Hydroxyl Ions
Diagram of an Alkaline Fuel Cell. 1: Hydrogen 2:Electron flow 3:Charge 4:Oxygen 5:Cathode 6:Electrolyte 7:Anode 8:Water 9:Hydroxyl Ions

The alkaline fuel cell (AFC), also known as the Bacon fuel cell after its British inventor, is one of the most developed fuel cell technologies and is the cell that flew Man to the Moon. NASA has used alkaline fuel cells since the mid-1960s, in Apollo-series missions and on the Space Shuttle. AFCs consume hydrogen and pure oxygen producing portable water, heat, and electricity. They are among the most efficient fuel cells, having the potential to reach 70%.

The fuel cell produces power through a redox reaction between hydrogen and oxygen. At the anode, hydrogen is oxidized according to the reaction:

\mathrm{2H}_2 + \mathrm{4OH}^- \longrightarrow \mathrm{4H}_2\mathrm{O} + \mathrm{4e}^- \left ( 1 \right )

producing water and releasing two electrons. The electrons flow through an external circuit and return to the cathode, reducing oxygen in the reaction:

\mathrm{O}_2 + \mathrm{2H}_2\mathrm{O} + \mathrm{4e}^- \longrightarrow \mathrm{4OH}^- \left ( 2 \right )

producing hydroxide ions. The net reaction consumes one oxygen molecule and two hydrogen molecules in the production of two water molecules. Electricity and heat are formed as by-products of this reaction.

The two electrodes are separated by a porous matrix saturated with an aqueous alkaline solution, such as potassium hydroxide (KOH). Aqueous alkaline solutions do not reject carbon dioxide (CO2) so the fuel cell is easily poisoned. Because of this, the fuel cell requires pure oxygen, or at least purified air. These processes are relatively expensive, so not many continual developments are being made on AFC technology.

AFCs are, however, the cheapest of fuel cells to manufacture. The catalyst required for the electrodes can be any of a number of different chemicals that are relatively inexpensive compared to those required for other types of fuel cells.

The commerical prospects for AFCs lie largely with the recently developed bi-polar plate version of this technology, considereably superior in performance to earlier mono-plate versions.

Another very interesting recent development (though not necessartily for high power applications) is the solid-state alkaline fuel cell, utilising anion-exchange membranes rather than a liquid. This work is pioneered at the University of Surrey in the United Kingdom. See details at http://www.surrey.ac.uk/~chs1jv/.

See also

  • Hydrazine
  • Hydrogen technologies

External links

  • Astris Energi Inc
  • Cenergie Corporation plc - note [1] and [2]
  • Independent Power
  • Intensys


 

Fuel Cells
Types:  AFC | BE | DBFC | DEFC | DMFC | EGFC | FAFC | MCFC | MFC | MHFC | PAFC | PCFC | PEC | PEMFC | RFC | rfc | SOFC | ZFC 
Other: Hydrogen Economy | Hydrogen storage | Hydrogen station | Hydrogen Vehicles


 

Sustainability and Development of Energy   Edit
Conversion | Development and Use | Sustainable Energy | Conservation | Transportation



 

Retrieved from "http://en.wikipedia.org/wiki/Alkaline_fuel_cell"

Categories: Fuel cells | Environment | Sustainability | Sustainable technologies | Climate change

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