Trying
to better understand underwater volcanoes, microscopic life, Arctic winds
Scientists
from the University of Rhode Island’s Graduate School of Oceanography spent
weeks at sea last summer on research expeditions designed to gain a better
understanding of underwater volcanoes, microscopic life and Arctic winds.
The
summer expeditions are representative of the wide variety of subjects that URI
oceanographers study and the leadership role the University plays in gaining
new knowledge about the world’s oceans.
In
a NASA-led expedition to the North Pacific, URI oceanographers and graduate
students were among 100 scientists participating in a month-long project to
study microscopic organisms that live deep in the ocean and play a critical
role in removing carbon dioxide from Earth’s atmosphere.
This first-of-its-kind effort to explore the impact of plankton on Earth’s carbon cycle used two research vessels to deploy advanced underwater robotics and other instruments to depths up to a half mile, where little or no sunlight penetrates. In these regions, carbon produced by plankton can be confined in pockets and kept out of Earth’s atmosphere for decades, or even thousands of years.
Phytoplankton
are of particular interest to researchers because they play a key role in
Earth’s climate by removing heat-trapping carbon dioxide from the atmosphere
through photosynthesis. Yet a detailed account of what becomes of that carbon —
how much of it goes where within the Earth and for how long — has beset
scientists for decades.
“Our
experiments and sampling were all successful,” said URI Oceanography Professor
Tatiana Rynearson. “The project collected terrabytes of data and thousands of
samples that will provide insights into the mechanisms of carbon export from
the oceans’ surface waters.”
In
another NASA-led expedition, this time to an underwater volcano off the coast
of Hawaii, URI used its Inner Space Center to help NASA learn how to use
telepresence in the way it may use it for space exploration. The researchers
blended ocean and space research to better understand if the watery worlds
found on moons and planets in our solar system offer conditions that could
support microbial life.
According
to Dwight Coleman, director of the Inner Space Center, the type of hydrothermal
venting at the Lō`ihi Seamount is a good representation of conditions
scientists believe exist on certain moons in the outer solar system.
“We
accomplished every goal that we set out to accomplish,” said Coleman. “The
primary goal was to simply use the Center as it was designed to support
seagoing ship-based ocean exploration involving a multidisciplinary team of
scientists. It worked perfectly for that.”
In
a follow-up expedition next year, a delay in the Inner Space Center
communications system will be simulated to represent the transmission delays
likely to occur during space exploration.
In
the Beaufort Sea north of Alaska, URI oceanographer Robert Campbell and two
students joined a project to understand how winds and ocean physics influence
plankton and fish prey availability and how marine mammal and seabirds respond
to varying conditions.
The URI team was responsible for describing the changes in abundance and distribution of zooplankton in response to the upwelling of deep water during east winds and determining the nutritional quality of zooplankton for animals that feed on it.
The URI team was responsible for describing the changes in abundance and distribution of zooplankton in response to the upwelling of deep water during east winds and determining the nutritional quality of zooplankton for animals that feed on it.
This
was the second year in a row that Campbell has participated in the project.
“The
conditions we encountered in the two years were dramatically different,” he
said. “In 2017, there was no ice and we encountered two large upwelling events
with strong winds from the east. In contrast, during the 2018 cruise the entire
region was still covered in ice and mostly light, non-upwelling winds
dominated. We anticipate that the two contrasting years will provide a nice
comparison in the distribution, abundance, and nutritional quality of the
zooplankton prey field.”
URI’s
Narragansett Bay Campus is home to the URI Graduate School of Oceanography
(GSO), one of the world’s premier oceanographic institutions.
Founded in 1961, GSO has built a reputation for excellence in deep water oceanographic research, coastal planning and management, sustainable fisheries and monitoring the health of Narragansett Bay. With operations, researchers, faculty and students worldwide, the Bay Campus education and outreach programs train the next generation of scientists and policymakers, while ensuring Rhode Island’s K-12 teachers and students gain an appreciation for the importance of ocean science through a variety of hands-on programs.
Founded in 1961, GSO has built a reputation for excellence in deep water oceanographic research, coastal planning and management, sustainable fisheries and monitoring the health of Narragansett Bay. With operations, researchers, faculty and students worldwide, the Bay Campus education and outreach programs train the next generation of scientists and policymakers, while ensuring Rhode Island’s K-12 teachers and students gain an appreciation for the importance of ocean science through a variety of hands-on programs.
On Nov.
6, Rhode Islanders will vote on Question 2, a $70 million higher education
general obligation bond that includes $45 million for upgrades to the
Narragansett Bay Campus. If approved, proceeds from the bond will be used to
improve the GSO’s pier (required to accommodate a newly awarded Regional Class
Research Vessel from the National Science Foundation worth about $125 million),
construct a 20,000-square-foot Ocean Technology building, a 12,000-square-foot
Marine Operations building and fund other necessary improvements to campus
facilities.
