In late September, two teachers from Griffin-Spalding County Schools participating in the Georgia Tech AMP-IT-UP program were given an opportunity to join a research expedition in the Gulf of Mexico. Cheryl Wilder from Kennedy Road Middle School and Kathy Duke from Rehoboth Road Middle School are seventh-grade life science teachers that received the chance to experience real-world research with ECOGIG (Ecosystem Impacts of Oil and Gas Inputs in the Gulf,) an organization founded by the Gulf of Mexico Research Initiative after the Deepwater Horizon oil spill in 2010. The research was relevant not only for the teachers but also for their students, who have been studying AMP-IT-UP curriculum modules on the Gulf ecosystems.
The AMP-IT-UP (Advanced Manufacturing and Prototyping Integrated to Unlock Potential) program is a multi-year NSF Math and Science Partnership whose mission is to cultivate the next generation of creative science, technology, engineering, and mathematics (STEM) innovators. It is a collaborative partnership between Georgia Tech and Griffin-Spalding County Schools. The Center for Education Integrating Science, Mathematics, and Computing (CEISMC) has partnered with the School of Mechanical Engineering to design math and science modules that bring advanced manufacturing and STEM themes to middle and high school classrooms; for example, AMP-IT-UP teachers Duke and Wilder are teaching their seventh graders three modules on ocean ecology, two of which are based on ECOGIG research. Each module profiles a member of the Georgia Tech faculty, connecting students in Griffin to the cutting-edge research being done at Georgia Tech and at the University of Georgia.
"I was very excited about going," said Wilder. "That was an opportunity of a lifetime – just to be a part of that whole process. A lot of times [students] don't get the science connection to the real world, and I'm hoping that through my experience, they'll be able to see that this is going on in other parts of the world – people are being impacted, the water is being impacted, the organisms in the sea are being impacted – and what can be done about it," shared Wilder. The teachers played an important role in collecting water samples on the cruise and gained firsthand experience with rosettes that measure the conductivity, temperature, and depth of water. Duke shared: "My job was to collect water samples for Dr. Mandy Joye, who is at the University of Georgia. We collected [samples] from the surface, from a halfway point, and from the bottom of the ocean; we froze some of those samples, and they were put in coolers and shipped to the university for her to start working on her research with those samples.”
Dr. Annalisa Bracco, from the School of Earth and Atmospheric Sciences at Georgia Tech, is a principal investigator for ECOGIG who partnered with CEISMC to design these AMP-IT-UP modules and organized for the teachers to join the cruise. “It is not easy to find space on those cruises to help with research, and it was a great opportunity for them because they have been teaching modules specifically on that subject,” said Bracco.
The teachers traveled to various sites throughout the Gulf, including to the GC600 site, which is a natural oil seep. According to Bracco, ECOGIG scientists, including Dr. Joe Montoya at Georgia Tech, have found that there is increased biological activity in areas with natural oil seeps because the rising bubbles of oil also carry to the surface water that is rich in nutrients, which is beneficial to plankton. ECOGIG is able to measure the amount of productivity not only by measuring plankton but also by examining the amount of marine snow, or organic material, in that area; the amount of marine snow varies depending on proximity to natural seeps and seasons. “You can get it more in some seasons because you may have some Mississippi River water that contains a lot of nutrients from land, so the ocean gets fertilized, essentially,” said Bracco. While current measurements at GC600 are primarily from natural marine snow, polluting events such as the Deepwater Horizon oil spill can contribute to an increase in the phenomenon.
Wilder described how going out to the different sites impacted her perspective on the Gulf of Mexico. “We went to three different sites, and it just blew my mind how you can go to one site and the water is pretty and blue, and go to another site and it is black,” said Wilder. “You could smell the oil and it was a very distinct odor,” she added. Both teachers were able to collect oil samples from the Taylor Energy Site, where there has been an ongoing oil spill since Hurricane Ivan in 2004 caused damage to the Mississippi Canyon 20-A production platform. Wilder and Duke plan to show the samples from the Taylor Energy Site to their students, who are even more excited about the classroom modules because of their teachers’ experiences.
This cruise is an example of how AMP-IT-UP is connecting teachers and students in Griffin to innovative research outside of the school district. The teachers thanked AMP-IT-UP for providing such a unique experience for educators and for bringing new enthusiasm to the classroom. “The AMP-IT-UP program has been absolutely wonderful for me because it has made me look at the way I teach science. In this way, you present students with a problem and then they need to come up with a possible solution. They gather data and decide: maybe we could have done this a better way or another way. Equipment doesn’t always work; you don’t always get the samples you need. It’s not foolproof, so they’re learning that,” said Duke. She continued, “I want to thank the AMP-IT-UP program for making this opportunity available. Not many times do classroom teachers get to go and do something like this; we were doing research firsthand and it was so impactful to me, just how I think about what they’re doing – their mechanical knowledge, their physics knowledge, their chemistry – how it all works together. It was really, really awesome.”
Advanced Manufacturing and Prototyping Integrated To Unlock Potential (AMP-IT-UP)
is made possible by a grant from the National Science Foundation (Award Number: 1238089)
By Rosemary T. Pitrone