What's New Archive
In the Crow's Nest, watching for a 'blow'. "Thar she blows". Photo courtesy of the New Bedford Whaling Museum.
Citizen scientists have a new opportunity to help reconstruct past climate by transcribing data from whaling ship logs. A massive collaboration among government and university scientists, archivists and museum curators, has unveiled Old Weather: Whaling, a sister project of Old Weather that is focused on the Pacific Arctic whaling industry that began in 1849. Volunteers mine massive amounts of sea-ice and weather data from the ship’s logs -- along with amazing stories of the Arctic whalemen. These data are fed to state-of-the-art retrospective analysis (reanalysis) systems and provide ground-truth for sea-ice and climate models, all contributing toward better understanding of the Arctic climate of the future.
Read more about Old Weather and Old Weather: Whaling as well as feature stories on NOAA Research and UW Today from the University of Washington.
Overview of the planned survey area for the Hydrothermal Hunt. Image credit: SIO
Starting Nov. 21st, NOAA PMEL, UW/JISAO and OSU/CIMRS scientists will explore the Mariana Back-arc, a volcanically active region expected to be teeming with life. Research will take place aboard the Schmidt Ocean Institute’s Falkor and will use the autonomous underwater vehicle (AUV) Sentry and CTD to detect and characterize hydrothermal vents found in the region. The team will start by surveying and identifying active vent sites along the Mariana back-arc, and will characterize each site by depth, geologic setting, temperature, chemical composition, and rise heights of hydrothermal plumes. A follow-up expedition next year will use the results found in this survey, and return to use a remotely operated vehicle (ROV) to explore and sample the new sites found during this cruise.
Visit the Schmidt Ocean Institute cruise blog and the NOAA PMEL Earth-Ocean Interactions program for updates.
The locations of 11 Ocean Noise Reference Stations are depicted above and range from as far north as the Arctic coast of Alaska to American Samoa in the South Pacific.
Monitoring baseline ocean noise is critically important to understand both natural and anthropogenic changes in the marine ambient sound environment. As of this week, a network of 11 ocean noise reference stations has been established in U.S. waters to measure changes and trends in natural and man-made ocean noise. Natural sounds ranging from whale calls and volcanoes to anthropogenic sounds from shipping and oil/gas exploration are recorded by the moored, underwater hydrophones developed by PMEL engineers and scientists and deployed in collaboration with NMFS-OST, all the Fisheries Science Centers, NOS Marine Sanctuaries, and the National Park Service. The establishment of a long-term record provides fundamental data needed to understand how increased noise in the ocean may affect marine life and ocean health.
For more information on this collaborative project, see NOAA/PMEL Acoustics, NOAA/PMEL Ocean Noise Reference Station Network, and the NOAA/NMFS-OST feature story.
The global distribution of aragonite saturation at 50 meters depth.The areas most vulnerable to ocean acidification are regions where the saturation of aragonite is lower. Aragonite is a calcium carbonate mineral that shellfish use to build their shells. (NOAA)
New NOAA research in Global Biogeochemical Cycles maps the distribution of aragonite saturation state in both surface and subsurface waters of the global ocean and provides further evidence that ocean acidification is happening on a global scale. The study identifies the Arctic and Antarctic oceans, and the upwelling ocean waters off the west coasts of North America, South America and Africa as regions that are especially vulnerable to ocean acidification. The most vulnerable areas of the global ocean are being hit with a double whammy of sorts. In these areas, deep ocean waters that are naturally rich in carbon dioxide are upwelling and mixing with surface waters that are absorbing carbon dioxide from the atmosphere, which comes primarily from human-caused fossil fuel emissions.
Read the NOAA press release, the article in Global Biogeochemical Cycles, and visit the NOAA PMEL Carbon Program and the NOAA National Centers for Environmental Information webpages.
Cover art by Christopher Moore, NOAA/PMEL.
A new theme issue of the Royal Society Philosophical Transactions A called ‘Tsunamis: bridging science, engineering and society’ looks at the lessons learned from tsunamis over the last ten years. The issue describes state of the art methodologies, standards for warnings, summarizes recent advances in basic understanding and identifies cross-disciplinary challenges.
PMEL scientists served as editors for the issue, authored several articles in the issue, and contributed the cover graphic, which depicts the forecast of the 2011 Japan tsunami made by the PMEL tsunami research team while the tsunami was still propagating across the Pacific. The goal of this issue is to bring the science, engineering and societal needs together to help build coastal resilience and reduce losses of life and property.
Read more about the NOAA Center for Tsunami Research.
Hydrothermal Fluid and Particle Sampler on front of the Alvin submersible, in the process of collecting a high-temperature water sample from the Main Endeavour Field. Photo credit: WHOI
A paper just published in Nature Geoscience shows a newly recognized role for hydrothermal vents in the global carbon cycle. This new research, by PMEL/JISAO researcher David Butterfield and colleagues, shows that hydrothermal vents may act as a recycling and decomposition system for dissolved organic carbon (DOC), an important constituent of the global carbon pool. The scientists found that high temperatures, like those found at hydrothermal vents, can effectively remove DOC not broken down by other processes, like microbial or sedimentary degradation. The implication for the global carbon cycle is that hydrothermal vents act as the ocean’s ‘pressure cooker’, breaking down and removing unreactive and old carbon that would otherwise persist indefinitely.
Read more about PMEL’s Earth-Ocean Interactions Program or the article in Nature Geoscience.
Dynamical downscaling of the global model (left) resolves finer scale features on the Bering Sea Shelf (right) viewable through the Alaskan Ocean Observing System website.
Al Hermann and Wei Cheng, PMEL/JISAO researchers with EcoFOCI are part of a new NOAA-funded study to project large-scale environmental changes in the US Arctic through the process of dynamical downscaling. This process uses the most recent set of global climate models (CMIP5) to simulate regional events in the Bering Sea. Paired with upper trophic level and management models, the project will provide a variety of projections of the Bering Sea ecosystem with varying fishing and climate scenarios.
The CLIMate project seeks to understand how large-scale changes in the atmosphere and oceans will manifest themselves in the Bering Sea, how such environmental changes will affect commercially important fish and other species, and how management strategies could be beneficially modified in the face of anticipated changes in mean conditions, variability, and the likelihood of extreme events.
For more information, please see news releases by NOAA Fisheries and the University of Washington and find more data products at the Alaska Ocean Observing System.
Current sea surface temperature anomalies in the tropical pacific, indicative of a strong El Niño.
Research and commentary articles just published online in Nature Climate Change by NOAA/PMEL Senior Scientist Michael McPhaden and collaborators highlights the need for continued study into El Niño causes and effects.
McPhaden’s commentary explores possible reasons why the much anticipated El Niño of 2014 failed to materialize, while an unforeseen strong El Niño is developing now. In the same issue, a review paper by McPhaden and colleagues explores the connection between global warming and El Niño/La Niña events. Model results indicate that extreme El Niño and La Niña events will increase in number and intensity as the climate continues to warm.
Read the commentary and research review on Nature Climate Change and the NOAA Press Release about current El Niño research.
Seattle and the surrounding Puget Sound.
NOAA/PMEL Scientist Dr. Simone Alin and UW/JISAO Scientist Nick Bond took part in media event on July 30 highlighting the unusual conditions found in the Puget Sound in 2015. The Sound has been abnormally warm, fueled by the warm water Blob off the Pacific coast, warm weather and lower than usual river inflow. Scientists note that the timing of warmer waters and lower pH conditions have come earlier this year.
Dr. Alin pointed out “It is tempting to compare conditions this year to our projected future climate in the second half of this century. However, this just represents the temperature part of future climate impact on the oceans. We would also expect a sizeable increase in carbon dioxide in the atmosphere and oceans between 2050 and 2100 compared to now, which would worsen ecosystem conditions considerably relative to what we are seeing with the temperature increase alone.”
Read the press release.
Dr. Johnson and Dr. Purkey prepare to deploy an Argo float in the Indian Ocean.
Dr. Sarah Purkey’s doctoral dissertation, “The Abyssal Ocean’s Contributions to the Global Energy and Sea Level Budgets Between the 1990s and 2000s”, was recently chosen to receive the 2015 University of Washington Graduate School’s Distinguished Dissertation Award in the Physical Sciences & Engineering category. Dr. Purkey started her oceanographic career in 2007 as a UW/JISAO research scientist/engineer working at PMEL. She was resident at PMEL for her graduate research, advised by PMEL Oceanographer Dr. Gregory C. Johnson in his capacity as an Affiliate Professor with the School of Oceanography, University of Washington. Dr. Purkey is currently a Postdoctoral Fellow at Columbia University’s Lamont-Doherty Earth Observatory.