Examine possible correlations between independently acquired datasets dynamically using open source methods and sources.
This lesson will take us one week to complete. Please refer to the Course Syllabus for specific timeframes and due dates. Specific directions for the assignment below can be found within this lesson.
Requirements | Assignment Details |
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To Do | Read and familiarize yourself with all the Lesson 6 materials. |
Read | Week 9: Read the following articles, in order:
(Note, yes, you are supposed to reread the Science article "Impact of Shale Gas Development on Regional Water Quality" at the end.)
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Assignment | Week 9:
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If you have any questions, please post them to our Questions? discussion forum (not email), located under the Discussions tab in Canvas. I will check that discussion forum daily to respond. While you are there, feel free to post your own responses if you, too, are able to help out a classmate.
We will begin to identify potential ethical issues in the language of science in the article titled "Impact of shale gas development on regional water quality" which appeared in the May 16th, 2013 issue of the journal Science.
In this article, we will be looking for potential ethical issues that could arise from the scientific study of the impact of shale gas on regional quality water quality.
We will look specifically at the language used in the article to help us locate issues worth further ethical consideration. Later on, we will use the Ethical Dimensions of Scientific Research approach to help us think about where else to look. There is potential for significant ethical issues because the article deals with two issues of immediate importance to contemporary society, namely, development of the energy sector and water quality.
The first sentence of the background indicates to us that natural gas is of significant concern to various regions around the world because of its ability to be a relatively clean energy source as well as reducing dependence on energy imports. As such, we are immediately told that this issue we are about to look at has significant political and environmental importance, often linking us to a variety of ethical considerations. As a transition fuel, methane is also important because it helps is to reduce emissions of CO2 from fossil fuels, various criteria pollutants (NOx, O3, CO, SO2, pm, Pb), and mercury emissions from coal burning, specifically.
Hydraulic fracturing as a way of extracting difficult to reach methane sources has the further appeal of being economically feasible. The process of hydraulic fracturing is a high-pressure process intended to crack rock about 1km below the surface and, as such, this process presents environmental risks to underground water reservoirs through possible gas migration via fractures, the later discharge of the wastewater initially used as hydraulic fluid, and accidental spills in the management of wastewater. What goes unsaid in stating these environmental risks are what these risks also pose to people exposed to such contaminants, but understand that environmental risks are almost always linked to risks to human health, livelihoods, and wellbeing.
As it is stated in the advances in paragraph, the most common problem is with faulty seals around the well casing to prevent leakage of methane. However, the incidence rate of faulty seals is in the range of 1-3% of installed wells. Methane has been detected in areas around well drilling, but there is controversy as to whether or not the methane that was detected was due to the drilling or other natural processes. Without data as to what the conditions were before drilling, what they refer to here as a pre-drilling baseline, it is difficult to determine current conditions from "normal" conditions, as methane has been known to enter into the water table naturally in some of these areas before drilling occurred. As we will see in this article, methods of measuring methane isotopes were used to help answer some of these questions.
Wastewater management of the used hydraulic fracturing fluids is going to dominate environmental debate because wastewater contains both significant chemical additives for the fracturing process as well as vast quantities of heavy metals and radioactive contaminants brought up to the surface from deep underground. As wastewater can only be reused so many times, and as fields mature, there will be growing pressure on finding better strategies for managing the wastewater.
Looking more specifically at the contaminants found in used fracturing fluid, the urgency and risks associated with wastewater management become readily apparent. According to the article, waste management can be more effective through improving three significant areas of research, that is: better modeling of what happens to contaminants of concern, increased long-term monitoring of the wells, and the dissemination of data (which includes improving transparency in the fluid contents). The paper identifies three significant impediments, however, to peer-reviewed research into the environmental impacts of well drilling. First, confidentiality requirements dictated by trade secret laws and what is legal during investigations keep information hidden. Second, the expedited rate of development is making it difficult to conduct studies within a reasonable timeframe, and the limited funds available for research into the impacts of horizontal well-drilling for shale gas. This becomes a problem because the burden becomes to prove harm is being done by this process by a wide range of stakeholders local to drilling sites, as opposed to the burden of having to prove that no harm is being done, which would be put on the drilling and energy companies.
Now, you will want to work through the entire article, reading in a close manner such as this.
These articles provide significant insight into the water pollution risks concerning wastewater from hydraulic fracturing, focusing mainly on the Marcellus Shale region. You will see some common findings emerge in these three readings that pose some concern and elicit recommendations from the authors. Pay attention to these findings.
These articles provide significant insight into the risks concerning methane migration into groundwater from hydraulic fracturing, focusing mainly on the Marcellus Shale region. Like the articles from the prevision section, you will see some common findings emerge in these three readings that pose some concern and elicit recommendations from the authors. Pay attention to these findings.
Links
[1] http://www.publicdomainfiles.com/browse.php?q=all&s=0&o=popular&a=23&m=all
[2] https://www.e-education.psu.edu/bioet533/sites/www.e-education.psu.edu.bioet533/files/ImpactofShale.pdf
[3] http://onlinelibrary.wiley.com.ezaccess.libraries.psu.edu/doi/10.1111/j.1539-6924.2011.01757.x/abstract
[4] http://www.sciencedirect.com.ezaccess.libraries.psu.edu/science/article/pii/S0883292712002752
[5] https://www.e-education.psu.edu/bioet533/sites/www.e-education.psu.edu.bioet533/files/media/gas-_Hydraulic-Fract-chemicals-2011-report.pdf
[6] http://www.sciencedirect.com/science/article/pii/S0883292711004732
[7] http://www.pnas.org/content/108/20/8172.full.pdf+html
[8] https://www.ogj.com/1/vol-109/issue-49/exploration-development/methane-in-pennsylvania-water-full.html
[9] http://www.pnas.org/content/108/37/E664.full.pdf+html
[10] http://scorecard.goodguide.com/chemical-profiles/
[11] http://fracfocus.org/
[12] https://upload.wikimedia.org/wikipedia/commons/2/26/Abandoned_gas_well_in_high_grass.jpg
[13] https://commons.wikimedia.org/wiki/File:Abandoned_gas_well_in_high_grass.jpg