Glasgow/Goals/FuelCells

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<font face=georgia color=#00FFFF size=4>Microbial Fuel Cells</font><br>
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<BR>
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<font face=georgia color=#0000FF size=4>'''Microbial Fuel Cells'''</font><br>
[[Image:Fuelcell.JPG|frame|Basic Microbial Fuel Cell]]
[[Image:Fuelcell.JPG|frame|Basic Microbial Fuel Cell]]
<br>
<br>
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Most microbial cells are electrochemically inactive. The electron transfer from microbial cells to the electrode is facilitated by mediators such as thionine, methyl viologen (methyl blue), neutral red etc, and of the mediators available are expensive and toxic. Microbial fuel cells produce power by use of a microbial cell-permeable chemical mediator, which in the oxidised form intercepts a proportion of NADH (nicotinamide adenine dinucleotide) within the microbial cell and oxidises it to NAD+. The now reduced form of mediator is also cell-permeable and diffuses away from the microbial cell to the anode where, the reduced redox mediator is then electro-catalytically re-oxidised. In addition, cell metabolism produces protons in the anodic chamber, which may migrate through a proton selective membrane to the cathodic chamber. In the latter, they are consumed by ferricyanide (Fe3-(CN)6) and incoming electrons (via the external circuit) reducing it to ferrocyanide (Fe4-(CN)6 ). The oxidised mediator is then free to repeat the cycle. This cycling continually drains off metabolic reducing power from the microbial cells to give electrical power at the electrodes.  
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Most microbial cells are electrochemically inactive. The electron transfer from microbial cells to the electrode is facilitated by mediators such as thionine, methyl viologen (methyl blue), neutral red etc, and of the mediators available are expensive and toxic. Microbial fuel cells produce power by use of a microbial cell-permeable chemical mediator, which in the oxidised form intercepts a proportion of NADH (nicotinamide adenine dinucleotide) within the microbial cell and oxidises it to NAD+. The now reduced form of mediator is also cell-permeable and diffuses away from the microbial cell to the anode where, the reduced redox mediator is then electro-catalytically re-oxidised. In addition, cell metabolism produces protons in the anodic chamber, which may migrate through a proton selective membrane to the cathodic chamber. In the latter, they are consumed by ferricyanide (Fe3-(CN)6) and incoming electrons (via the external circuit) reducing it to ferrocyanide (Fe4-(CN)6 ). The oxidised mediator is then free to repeat the cycle. This cycling continually drains off metabolic reducing power from the microbial cells to give electrical power at the electrodes.  Our mediator is pyocyanin and this has been shown to improve performance of fuel cells [https://2007.igem.org/Glasgow/Wetlab/References (Rabaey ''et al'', 2003)].  
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[[Image:IMG 4434.JPG|250px]]
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[[Image:IMG 4442.JPG]]
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<font face=georgia color=#0000FF size=4>'''Our Own Microbial Fuel Cells'''</font><br>
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<br>
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We decided to give microbial fuels cells a go ourselves.  Starting with yeast as our organism, glucose as our energy source and methlylene blue as our mediator.  The kits we used were ordered from the University of Reading.  This is the initial recipe we followed:
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{| cellspacing="6px" cellpadding="16" border="0" width="100%"
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|-
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|[[Image:IMG 4468.JPG|250px]]
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|'''Materials'''
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<br>
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For each cell:
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*Perspex fuel cell
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*Cation exchange membrane
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*Carbonfibre elecrodes
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*10 cm2 of J-cloth
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*10 ml syringes
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*2 leads with corc clips
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*0.5V range volt meter
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<br>
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*Thick slurry of dried bakers yeast in 0.1M phosphate buffer.
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*5 ml methylene blue solution (10mM)
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*5 ml glucose solution (1M)
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*10 ml potassium hexacyanoferrate (3) solution (0.02M) (aka potassium ferricyanide)
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*Phosphate buffer (0.1M)
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Into one side of the cell inject 10 ml hexacyanoferrate (III) solution (in phosphate buffer).  Into the other side inject 3.3 ml yeast slurry, 3.3 ml methylene blue solution, and 3 ml glucose solution.  Each side of the cell holds 10 ml.  Make sure they are tight and sealed (can use vasceline) because they are prone to leakage.  Electrodes work best if the carbon fibre is rolled at the outer extremity.<br>
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<BR>
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<font face=georgia color=#0000FF size=4>'''Comparison of open circuit readings'''</font><br>
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[[Image: MFC_setup.png|frame]]
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[[Image: MFC_graph.png|center]]
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<br>
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<br>
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<font face=georgia color=#0000FF size=4>'''Fuel Cell Assembly'''</font><br>
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|[[Image:IMG 4434.JPG|250px]]
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|[[Image:IMG 4442.JPG|250px]]
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|[[Image:IMG 4458.JPG|250px]]</center>
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<center>
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|[[Image:IMG 4465.JPG|250px]]
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|[[Image:IMG 4471.JPG|250px]]
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|[[Image:IMG 4476.JPG|250px]]</center>
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Latest revision as of 15:52, 26 October 2007

Uog.jpg Back To
Glasgow's
Main Page
Back To
Glasgow's
Project Page


Microbial Fuel Cells

Basic Microbial Fuel Cell


Most microbial cells are electrochemically inactive. The electron transfer from microbial cells to the electrode is facilitated by mediators such as thionine, methyl viologen (methyl blue), neutral red etc, and of the mediators available are expensive and toxic. Microbial fuel cells produce power by use of a microbial cell-permeable chemical mediator, which in the oxidised form intercepts a proportion of NADH (nicotinamide adenine dinucleotide) within the microbial cell and oxidises it to NAD+. The now reduced form of mediator is also cell-permeable and diffuses away from the microbial cell to the anode where, the reduced redox mediator is then electro-catalytically re-oxidised. In addition, cell metabolism produces protons in the anodic chamber, which may migrate through a proton selective membrane to the cathodic chamber. In the latter, they are consumed by ferricyanide (Fe3-(CN)6) and incoming electrons (via the external circuit) reducing it to ferrocyanide (Fe4-(CN)6 ). The oxidised mediator is then free to repeat the cycle. This cycling continually drains off metabolic reducing power from the microbial cells to give electrical power at the electrodes. Our mediator is pyocyanin and this has been shown to improve performance of fuel cells (Rabaey et al, 2003).

Our Own Microbial Fuel Cells

We decided to give microbial fuels cells a go ourselves. Starting with yeast as our organism, glucose as our energy source and methlylene blue as our mediator. The kits we used were ordered from the University of Reading. This is the initial recipe we followed:

IMG 4468.JPG Materials


For each cell:

  • Perspex fuel cell
  • Cation exchange membrane
  • Carbonfibre elecrodes
  • 10 cm2 of J-cloth
  • 10 ml syringes
  • 2 leads with corc clips
  • 0.5V range volt meter


  • Thick slurry of dried bakers yeast in 0.1M phosphate buffer.
  • 5 ml methylene blue solution (10mM)
  • 5 ml glucose solution (1M)
  • 10 ml potassium hexacyanoferrate (3) solution (0.02M) (aka potassium ferricyanide)
  • Phosphate buffer (0.1M)

Into one side of the cell inject 10 ml hexacyanoferrate (III) solution (in phosphate buffer). Into the other side inject 3.3 ml yeast slurry, 3.3 ml methylene blue solution, and 3 ml glucose solution. Each side of the cell holds 10 ml. Make sure they are tight and sealed (can use vasceline) because they are prone to leakage. Electrodes work best if the carbon fibre is rolled at the outer extremity.


Comparison of open circuit readings

MFC setup.png
MFC graph.png



Fuel Cell Assembly

IMG 4434.JPG IMG 4442.JPG IMG 4458.JPG
IMG 4465.JPG IMG 4471.JPG IMG 4476.JPG