Team:Sheffield/Notebook
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The session was attended by all the undergrads and Andy. A twitter account was set up - already Steve is addicted. Catherine received lots of our quizzing emails. We emailed Xia Huang, regarding the paper Cao, X., et al. "A New Method for Water Desalination Using Microbial Desalination Cells." Environmental science & technology 43.18 (2009):7148-7152. We emailed Environmentalbiotech.com to find out more information about their grease eradication system and also Sheffield Forgemasters about their waste desposal methods. | The session was attended by all the undergrads and Andy. A twitter account was set up - already Steve is addicted. Catherine received lots of our quizzing emails. We emailed Xia Huang, regarding the paper Cao, X., et al. "A New Method for Water Desalination Using Microbial Desalination Cells." Environmental science & technology 43.18 (2009):7148-7152. We emailed Environmentalbiotech.com to find out more information about their grease eradication system and also Sheffield Forgemasters about their waste desposal methods. | ||
- | A few ideas about order and layout of the wiki were talked about during the meeting, with some designs being drawn up for a logo. We've decided to go with 'Drip & Drop'... or 'Drop & Drip' the water droplets as team mascots (still | + | A few ideas about order and layout of the wiki were talked about during the meeting, with some designs being drawn up for a logo. We've decided to go with 'Drip & Drop'... or 'Drop & Drip' the water droplets as team mascots (still a '''BIG''' ongoing debate between a few members). |
For desalination we decided an in-situ method would be most realistic. We would probably require well characterised halo-tolerant bacteria that can form a biofilm on an electrode. The system in theory would have a middle chamber where salt water is placed. Two flanking chambers would contain opposite electrodes sepatated from the middle chamber by selectively permeable membranes to either anions or cations. | For desalination we decided an in-situ method would be most realistic. We would probably require well characterised halo-tolerant bacteria that can form a biofilm on an electrode. The system in theory would have a middle chamber where salt water is placed. Two flanking chambers would contain opposite electrodes sepatated from the middle chamber by selectively permeable membranes to either anions or cations. |
Revision as of 09:06, 30 June 2010
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Friday 28th May 2010 - The whole team's very first brainstorm. Focusing on the water industry, we managed to develop some interesting ideas to research further, which includes:
1. Self healing pipes - a method for pipes to 'recover' from damage using bacterial biofilms. 2. Water desalination - how we can use specialised bacteria to lower the salt content of sea water to make it drinkable. 3. Lowering nitrate levels - using bacteria to lower nitrate levels in rivers, helping to promote healthy living conditions for fish 4. Carbon, nitrogen and phosphorus ratios - alteration of these using bacteria to inhibit growth of pathogenic bacteria 5. "Bactoshave!" - the bacterial shaving system... (patent pending)
The projects using search and destroy bacteria and self healing pipes were also considered in some detail. These will be discussed further during the next meeting. The Wikis we noted were: 2009: - Lethbridge, City College San Francisco and Missouri (bacterial fuel cells) - Columbia (sea water salt detection) - Wisconsin (increased resistance to salt) - Brussels (E.coli glue) - Newcastle (ion sequestering) 2008: - Heidelberg (targetting biofilms in pipes) - Brown (electrical reporting system) - Lethbridge (Search and destroy harmful hydrocarbons) - Calgary (pathogen killing machine) - Illinois (cholera detection) - Newcastle (B. subtillus as a biosensor) - Edinburgh (producing starch from cellulose and biomass) 2007: - Columbia (biosensor) - Glasgow (fuel cell) - MIT (clearing mercury contamination) - Turkey (pH dependent metal ion transporter) - South Utah (cyanide biosensor) - Brown (Lead contamination) 2006: - Edinburgh (sensing arsenic in drinking water)
The session was attended by all the undergrads and Andy. A twitter account was set up - already Steve is addicted. Catherine received lots of our quizzing emails. We emailed Xia Huang, regarding the paper Cao, X., et al. "A New Method for Water Desalination Using Microbial Desalination Cells." Environmental science & technology 43.18 (2009):7148-7152. We emailed Environmentalbiotech.com to find out more information about their grease eradication system and also Sheffield Forgemasters about their waste desposal methods. A few ideas about order and layout of the wiki were talked about during the meeting, with some designs being drawn up for a logo. We've decided to go with 'Drip & Drop'... or 'Drop & Drip' the water droplets as team mascots (still a BIG ongoing debate between a few members). For desalination we decided an in-situ method would be most realistic. We would probably require well characterised halo-tolerant bacteria that can form a biofilm on an electrode. The system in theory would have a middle chamber where salt water is placed. Two flanking chambers would contain opposite electrodes sepatated from the middle chamber by selectively permeable membranes to either anions or cations. A broad area we looked at on this day was the destruction/removal of pollutants/pathogens from water supply. Our potential targets included iron, lead, nitrates, pharmaceuticals, fats, oils, grease, sewage, various pathogens e.g. cholera and toxins. Final note - team lunch of pizza at Rise @ the Hallamshire is definitely something worth considering again.
We looked at the proteins TonB and ExbB for potential use in our desalination cell. The fuel cell desalination idea was adapted to just a desalination cell consisting of 3 chambers without electrodes, with chambers following the same order as before, but this time with a chloride sequestering bacteria in once chamber and a sodium sequestering bacteria in the other. This still needs some research to work out how realistic this idea is. We liked Newcastle's project from 2009 and considered how Bac-Man might be able to aid our project this year in this area. Removing nitrate in sewage treatment plants may also hold potential. We would be looking at ways to lower the amount of nitrate released by the plants using novel bacteria with a consortium of enzymes to 'mop up' the excess. The process could also be energy productive, opposed to energy consuming (where aeration is concerned). Lunch today - sandwiches in the sun in Weston Park. Tom, Narmada and Caroline revealed their vegetarianism to the rest of the group *gasp*.
Wednesday 30th June - 09:30 start to try tie up loose ends on initial ideas before the 14:00 meeting with team advisors.
notebookYou should make use of the calendar feature on the wiki and start a lab notebook. This may be looked at by the judges to see how your work progressed throughout the summer. It is a very useful organizational tool as well. |