Difference between revisions of "Team:UMaryland/Practices"

Latest revision as of 03:27, 19 October 2016

</div> </div> Human Practices

Human Practices
Reaching Out to the Community
Receiving feedback to integrate into our project

Interviewing Farmers at Markets about Methane

The big idea behind our project is finding a way to mitigate global warming by reducing the emission of a specific greenhouse gas, methane. Because we are interested in implementing our project in landfills and potentially cattle farms as well, we realized that we would have to work closely with the individuals who work in these locations. However, nothing can be achieved if these people share misconceptions about the problems that face our environment, how they are caused, and what can be done to stop them. When interviewing cattle farmers, we found that some of them did not see climate change as a relevant issue, so we decided to put together a brochure that describes the problem of climate change, how methane contributes, and what farmers can do to reduce their methane emissions.

Download the phamphlet in PDF format

Overall, we learned that cattle farmers have diverse points of view and cannot simply be put into one category. For example, through our interviews, we noted that that cattle farmers have differing views on whether climate change exists. Some believe that it is an urgent issue and that the impacts of it have been seen in agriculture, while others believe that temperatures repeat themselves in cycles and there has been no net impact on global weather. It is difficult to convince those who do not believe in global warming the urgency of reducing greenhouse gas emissions, so it is important to raise awareness of extreme climates around the globe and the impact that greenhouse gas emissions have.

Also, we learned that the government places significant regulations on farmers when it comes to their impact on the environment, and farmers may resent these regulations since they believe the regulations harm their farming practices. When farmers were asked what practices harm the environment, the main issues we heard about were chemicals running off into the Chesapeake Bay. Greenhouse gas emissions were often forgotten. We also heard individuals bring up the idea that farmers get bad publicity if they do not respect the environment, so more public pressure on farmers to reduce their greenhouse gas emissions could be very effective. Before our project could be implemented, we would need to raise awareness of climate change as a real problem, educate about the contributions of greenhouse gasses, and work with farmers to figure out a manageable implementation strategy that would not harm their practice.

Gude Landfill, Montgomery County MD

The Shady Grove Processing Center and Transfer Station is a landfill and waste energy facility located in Derwood, MD that processes 700 tons of waste annually. However only 5% of waste ends up in landfills, the rest is recycled or burned at waste energy facilities such as the one in Derwood. However, during the natural biodegradation of trash in landfills, a significant amount of methane is produced and can cause much damage to the atmosphere. Current measures taken to combat the release of methane into the atmosphere including flaring the gas.

The Gude landfill in Montgomery County, Maryland is an out-of-commission landfill that has been capped and no longer accepts trash. However it still releases large sums of methane and is a site of flaring. During our visit Dr. Karasik pointed out the network of piping that draw gas from the landfill, and different controls that exist to ensure all unmanned processes are running safely. He also discussed many complaints received in regards to juxtaposing such a facility near a residential area, further emphasizing the importance of waste management reform.

Towers used for flaring low quality methane

Gas from a landfill is collected through a complex series of wells, perforated pipes, and blowers which direct the gas mixture which is predominantly methane to a facility that either burns it for energy if it is of good quality, or flares it (combusts it) if it is of poor quality. Flaring may prevent methane from entering the atmosphere but is not 100% effective. Furthermore, it requires expensive infrastructure and a lot of regular maintenance. These features prevent many waste treatment facilities around the nation from implementing methane management solutions. Thus Dr. Karasik advised us that our project was of value and could greatly mitigate methane emissions if implemented correctly by providing a low-maintenance, and cost effective solution to the issue.

This visit was incredibly useful in directing the course of our research and determining more specifications for our bacteria. We discussed some of the limitations and restrictions we would have to keep in mind when designing our bioreactor, and how to integrate it into the existing infrastructures. We deduced that we would need to be able to make use of current methods of directing methane across landfills, such as the complex series of pipes and blowers, to direct the methane to our bioreactor. We were also given a rough estimate of the composition of gas we would be receiving so that we may plan how to separate and utilize the methane.

Contact Us

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-			<p>Our visit to the landfill informed us on the necessity and feasibility of our project design. In regards to necessity, we learned that current methods of removing methane, mainly flaring, are not efficient in generating energy. We learned that flaring requires constant upkeep of the facilities, large infrastructure, and manpower. Our solution aims to integrate landfills into the environment by adopting two metabolic pathways that eliminate methane. We directed our project focus to generating biomass from methane oxidation for subsequent energy generation. In regards to feasibility, we learned that the current piping system of landfills allows room for our project to be implemented. The piping system ensures that our bacteria would live in an environment with concentrated methane, and be able to sequester and oxidize it more efficiently than from the atmosphere.</p>
+			<p>The Shady Grove Processing Center and Transfer Station is a landfill and waste energy facility located in Derwood, MD that processes 700 tons of waste annually. However only 5% of waste ends up in landfills, the rest is recycled or burned at waste energy facilities such as the one in Derwood. However, during the natural biodegradation of trash in landfills, a significant amount of methane is produced and can cause much damage to the atmosphere. Current measures taken to combat the release of methane into the atmosphere including flaring the gas.</p>
+			<p>The Gude landfill in Montgomery County, Maryland is an out-of-commission landfill that has been capped and no longer accepts trash. However it still releases large sums of methane and is a site of flaring. During our visit Dr. Karasik pointed out the network of piping that draw gas from the landfill, and different controls that exist to ensure all unmanned processes are running safely. He also discussed many complaints received in regards to juxtaposing such a facility near a residential area, further emphasizing the importance of waste management reform.</p>
+			<div class="figure">
+				<img src="https://static.igem.org/mediawiki/2016/e/e2/T--UMaryland--flaring.jpg" class="figureImg" />
+				<small class="caption">Towers used for flaring low quality methane</small>
+			</div>
+			<p>Gas from a landfill is collected through a complex series of wells, perforated pipes, and blowers which direct the gas mixture which is predominantly methane to a facility that either burns it for energy if it is of good quality, or flares it (combusts it) if it is of poor quality. Flaring may prevent methane from entering the atmosphere but is not 100% effective. Furthermore, it requires expensive infrastructure and a lot of regular maintenance. These features prevent many waste treatment facilities around the nation from implementing methane management solutions. Thus Dr. Karasik advised us that our project was of value and could greatly mitigate methane emissions if implemented correctly by providing a low-maintenance, and cost effective solution to the issue. </p>
+			<p>This visit was incredibly useful in directing the course of our research and determining more specifications for our bacteria. We discussed some of the limitations and restrictions we would have to keep in mind when designing our bioreactor, and how to integrate it into the existing infrastructures. We deduced that we would need to be able to make use of current methods of directing methane across landfills, such as the complex series of pipes and blowers, to direct the methane to our bioreactor. We were also given  a rough estimate of the composition of gas we would be receiving so that we may plan how to separate and utilize the methane. </p>
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