Team:GeorgiaTech

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     <h2 class="onBlack">How does dissolved methane endanger our water?</h2>
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     <h2 class="onBlack">How does dissolved methane from fracking endanger our water?</h2>
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Look at this running stream and imagine how it would appear when contaminated with methane gas. If you pictured it as a flowing stream of seltzer water, then you're not far off.
Look at this running stream and imagine how it would appear when contaminated with methane gas. If you pictured it as a flowing stream of seltzer water, then you're not far off.
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The demand for natural gas to fuel growing industries has led to the development and increased use of fracking techniques to extract methane and other natural gases from shale outcroppings deep in the Earth's crust. These outcroppings often lie underneath freshwater aquifers, and when disturbed can release gases into the water supply posing health concerns for water well owners.  
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The demand for natural gas to fuel growing industries has led to the development and increased use of fracking techniques to extract methane and other natural gases from shale veins deep in the Earth's crust. In the extraction process, up to several million gallons of fracking fluid are pumped into the well, all of which must be later treated for methane and other hydrocarbon contaminants.  
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Our project aims to enable E. coli to produce soluble methane monooxygenase (sMMO) a protein capable of converting methane into less volatile methanol, which can then be treated by further remediation pathways.
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Our project aims to enable E. coli to produce soluble methane monooxygenase (sMMO) a protein capable of converting methane into less volatile methanol, which can then be treated by further remediation pathways or extracted for commercial use.
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   <a class="cover boxcaption" style="top: 405px" href="https://2014.igem.org/Team:GeorgiaTech/Project">
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     <h2 class="onBlack">How can we make </br> these environment saving bacteria?</h2>
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     <h2 class="onBlack">How can synthetic biology eliminate the methane threat?</h2>
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         <LI class="column" id="Macrogen" style="left: 40px;"><p><a href="http://www.macrogenusa.com/"><img src="https://static.igem.org/mediawiki/2014/3/34/Macrogen.jpg" width="274px" height="100px"></a></p></LI>
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Latest revision as of 18:40, 17 October 2014

How does dissolved methane from fracking endanger our water?

Look at this running stream and imagine how it would appear when contaminated with methane gas. If you pictured it as a flowing stream of seltzer water, then you're not far off.

The demand for natural gas to fuel growing industries has led to the development and increased use of fracking techniques to extract methane and other natural gases from shale veins deep in the Earth's crust. In the extraction process, up to several million gallons of fracking fluid are pumped into the well, all of which must be later treated for methane and other hydrocarbon contaminants.

Our project aims to enable E. coli to produce soluble methane monooxygenase (sMMO) a protein capable of converting methane into less volatile methanol, which can then be treated by further remediation pathways or extracted for commercial use.

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