Publications from CAFA funded projects. Sort by year, title, or project to view publications.
Author(s): Zhang. S., C. A. Stock, E. N. Curchitser, and R. Dussin
Project PI: CurchisterDOI: http://DOI:10.1029/2018JC014308
The supply of nitrogen is a primary limiting factor for the productivity of the Northeast United States (NEUS) continental shelf. In this study, a 12-year (1996–2007) retrospective physical-biogeochemical simulation over the Northwest Atlantic was used to analyze the mean and seasonal NEUS shelf nitrogen budget, including the connections between shelf subregions: the Gulf of Maine/Georges Bank (GoM/GB), and the Mid-Atlantic Bight (MAB). The model captures the primary mean and seasonal patterns of shelf circulation, nitrate, and plankton dynamics. Results confirm aspects of previous nitrogen budget analyses, including the dominance of offshore nitrogen influxes into the GoM/GB and the prominent role of riverine influxes and sedimentary denitrification in the MAB. However, detailed spatiotemporal analysis of nitrogen fluxes highlights the importance of dispersed inflows of shallow to intermediate depth waters (0–75 m), which can at times exceed the deep nitrogen influx emphasized in previous studies. A seasonal analysis shows a pronounced shift from the net import of nitrogen to the GoM/GB region during late fall and winter, to the net export of nitrogen from the region in the spring and early summer. The MAB, in contrast, consistently exports nitrogen to offshore waters. The prominence of the 0-75m nitrogen supply has implications for the roles of Labrador Slope Water and Atlantic Temperate Slope Water on the NEUS ecosystems, as Atlantic Temperate Slope Water has greater nitrate concentrations than Labrador Slope Water at depth but often less at the surface. Results suggest the need for further study of shallow to intermediate depth inflows beyond those from the Scotian Shelf, particularly during the fall/winter of net nitrogen inflow.
Author(s): Zhang, S., E.N. Curchitser, D. Kang, C.A. Stock and R. Dussin
Project PI: CurchisterDOI: http:// https://doi.org/10.1002/2017JC013402
The Gulf Stream (GS) region has intense mesoscale variability that can affect the supply of nutrients to the euphotic zone (Zeu). In this study, a recently developed high-resolution coupled physical-biological model is used to conduct a 25-year simulation in the Northwest Atlantic. The Reynolds decomposition method is applied to quantify the nitrate budget and shows that the mesoscale variability is important to the vertical nitrate supply over the GS region. The decomposition, however, cannot isolate eddy effects from those arising from other mesoscale phenomena. This limitation is addressed by analyzing a large sample of eddies detected and tracked from the 25-year simulation. The eddy composite structures indicate that positive nitrate anomalies within Zeu exist in both cyclonic eddies (CEs) and anticyclonic eddies (ACEs) over the GS region, and are even more pronounced in the ACEs. Our analysis further indicates that positive nitrate anomalies mostly originate from enhanced vertical advective flux rather than vertical turbulent diffusion. The eddy-wind interaction-induced Ekman pumping is very likely the mechanism driving the enhanced vertical motions and vertical nitrate transport within ACEs. This study suggests that the ACEs in GS region may play an important role in modulating the oceanic biogeochemical properties by fueling local biomass production through the persistent supply of nitrate.
Author(s): Pinsky, M.L., Reygondeau, G., Caddell, R., Palacios-Abrantes, J., Spijkers, J. & Cheung, W.W.L.
Project PI: PinskyDOI: http://doi.org/10.1126/science.aat2360
The ocean is a critical source of nutrition for billions of people, with potential to yield further food, profits, and employment in the future (1). But fisheries face a serious new challenge as climate change drives the ocean to conditions not experienced historically. Local, national, regional, and international fisheries are substantially underprepared for geographic shifts in marine animals driven by climate change over the coming decades. Fish and other animals have already shifted into new territory at a rate averaging 70 km per decade (2), and these shifts are expected to continue or accelerate (3). We show here that many species will likely shift across national and other political boundaries in the coming decades, creating the potential for conflict over newly shared resources.
Author(s): Morley, J. W., Selden, R. L., Latour, R. J., Frölicher, T. L., Seagraves, R. J., & Pinsky, M. L. (
Project PI: PinskyDOI: http://doi.org/10.1371/journal.pone.0196127
Recent shifts in the geographic distribution of marine species have been linked to shifts in preferred thermal habitats. These shifts in distribution have already posed challenges for living marine resource management, and there is a strong need for projections of how species might be impacted by future changes in ocean temperatures during the 21st century. We modeled thermal habitat for 686 marine species in the Atlantic and Pacific oceans using long-term ecological survey data from the North American continental shelves. These habitat models were coupled to output from sixteen general circulation models that were run under high (RCP 8.5) and low (RCP 2.6) future greenhouse gas emission scenarios over the 21st century to produce 32 possible future outcomes for each species. The models generally agreed on the magnitude and direction of future shifts for some species (448 or 429 under RCP 8.5 and RCP 2.6, respectively), but strongly disagreed for other species (116 or 120 respectively). This allowed us to identify species with more or less robust predictions. Future shifts in species distributions were generally poleward and followed the coastline, but also varied among regions and species. Species from the U.S. and Canadian west coast including the Gulf of Alaska had the highest projected magnitude shifts in distribution, and many species shifted more than 1000 km under the high greenhouse gas emissions scenario. Following a strong mitigation scenario consistent with the Paris Agreement would likely produce substantially smaller shifts and less disruption to marine management efforts. Our projections offer an important tool for identifying species, fisheries, and management efforts that are particularly vulnerable to climate change impacts.
Author(s): Gray SA, SB Scyphers
Project PI: ScyphersDOI: https://doi.org/10.1016/B978-0-12-805375-1.00022-2
Including stakeholders in environmental monitoring and research has been an increasingly recognized necessity for understanding the complex nature of marine social–ecological systems (SES). Stakeholder engagement and participation is often an essential ingredient for successful conservation and management. As a result, new inclusive approaches to scientific research have emerged under a broad umbrella often referred to as “citizen science.” These are collaborative research efforts that include stakeholders in the scientific process and strive to in various ways (1) decrease uncertainty of the dynamics of marine SES through collaborative data collection; (2) harness the expertise and knowledge of stakeholders that rely on marine resources to better understand these systems; and (3) provide a venue for more inclusive forms of resource and ecosystem management decision-making. Although the literature on citizen science shows that it is a popular way to collaboratively understand and collaboratively make decisions about natural resources, to date there is little information about how citizen science can specifically support social–ecological research and participatory decision-making in marine systems. In this chapter, we provide an overview of how participatory approaches to citizen science have been applied in marine research. Further, we theorize about the role that emerging online technologies may play in the future for collaborative science, decision-making, and marine policy.
Author(s): Muhling, Barbara, et al.
Project PI: JacoxDOI: https://calcofi.org/publications/calcofireports/v60/Vol60-Muhling.pdf
Juvenile north Pacific albacore (Thunnus alalunga) forage in the California Current System (CCS), supporting fisheries between Baja California and British Columbia.
Within the CCS, their distribution, abundance, and foraging behaviors are strongly variable interannually. Here, we use catch logbook data and trawl survey records to investigate how juvenile albacore in the CCS use their oceanographic environment, and how their distributions overlap with the habitats of four key forage species. We show that northern anchovy (Engraulis mordax) and hake
(Merluccius productus) habitat is associated with productive coastal waters found more inshore of core juvenile albacore habitat, whereas Pacific sardine (Sardinops sagax) and boreal clubhook squid (Onychoteuthis borealijaponica)
habitat overlaps more consistently with that of albacore. Our results can improve understanding of how albacore movements relate to foraging strategies, and why preyswitching behavior occurs. This has relevance for the development of ecosystem models for the CCS, and for the eventual implementation of ecosystem-based fishery management.
Author(s): Kang, Dujuan, and Enrique N. Curchitser
Project PI: CurchisterDOI: http://https://doi.org/10.1175/JPO-D-17-0063.1
The seasonal cycles of the mean kinetic energy (MKE) and eddy kinetic energy (EKE) are compared in an idealized flow as well as in a realistic simulation of the Gulf Stream (GS) region based on three commonly used definitions: orthogonal, nonorthogonal, and moving-average filtered decompositions of the kinetic energy (KE). It is shown that only the orthogonal KE decomposition can define the physically consistent MKE and EKE that precisely represents the KEs of the mean flow and eddies, respectively. The nonorthogonal KE decomposition gives rise to a residual term that contributes to the seasonal variability of the eddies, and therefore the obtained EKE is not precisely defined. The residual term is shown to exhibit more significant seasonal variability than EKE in both idealized and realistic GS flows. Neglecting its influence leads to an inaccurate evaluation of the seasonal variability of both the eddies and the total flow. The decomposition using a moving-average filter also results in a nonnegligible residual term in both idealized and realistic GS flows. This type of definition does not ensure conservation of the total KE, even if taking into account the residual term. Moreover, it is shown that the annual cycles of the three types of EKEs or MKEs have different phases and amplitudes. The local differences of the EKE cycles are very prominent in the GS off-coast domain; however, because of the spatial inhomogeneity, the area-mean differences may not be significant.
Author(s): Kang, D., E.N. Curchitser and A. Rosati
Project PI: CurchisterDOI: https://doi.org/10.1175/JPO-D-15-0235.1
The seasonal variability of the mean kinetic energy (MKE) and eddy kinetic energy (EKE) of the Gulf Stream (GS) is examined using high-resolution regional ocean model simulations. A set of three numerical experiments with different surface wind and buoyancy forcing is analyzed to investigate the mechanisms governing the seasonal cycle of upper ocean energetics. In the GS along-coast region, MKE has a significant seasonal cycle that peaks in summer, while EKE has two comparable peaks in May and September near the surface; the May peak decays rapidly with depth. In the off-coast region, MKE has a weak seasonal cycle that peaks in summer, while EKE has a dominant peak in May and a secondary peak in September near the surface. The May peak also decays with depth leaving the September peak as the only seasonal signal below 100 m. An analysis of the three numerical experiments suggests that the seasonal variability in the local wind forcing significantly impacts the September peak of the along-coast EKE through a local-flow barotropic instability process. Alternatively, the seasonal buoyancy forcing primarily impacts the flow baroclinic instability and is consequently related to the May peak of the upper ocean EKE in both regions. The analysis results indicate that the seasonal cycle of the along-coast MKE is influenced by both local energy generation by wind and the advection of energy from upstream regions. Finally, the MKE cycle and the September peak of EKE in the off-coast region are mainly affected by advection of energy from remote regions, giving rise to correlations with the seasonal cycle of remote winds.
Author(s): Kang, D., and E.N. Curchitser
Project PI: CurchisterDOI: https://doi.org/10.1175/JPO-D-14-0200.1
A detailed energetics analysis of the Gulf Stream (GS) and associated eddies is performed using a highresolution multidecadal regional ocean model simulation. The energy equations for the time-mean and timevarying flows are derived as a theoretical framework for the analysis. The eddy–mean flow energy components and their conversions show complex spatial distributions. In the along-coast region, the cross-stream and cross-bump variations are seen in the eddy–mean flow energy conversions, whereas in the off-coast region, a mixed positive–negative conversion pattern is observed. The local variations of the eddy–mean flow interaction are influenced by the varying bottom topography. When considering the domain-averaged energetics, the eddy–mean flow interaction shows significant along-stream variability. Upstream of Cape Hatteras, the energy is mainly transferred from the mean flow to the eddy field through barotropic and baroclinic instabilities. Upon separating from the coast, the GS becomes highly unstable and both energy conversions intensify. When the GS flows into the off-coast region, an inverse conversion from the eddy field to the mean flow dominates the power transfer. For the entire GS region, the mean current is intrinsically unstable and transfers 28.26 GW of kinetic energy and 26.80 GW of available potential energy to the eddy field. The mesoscale eddy kinetic energy is generated by mixed barotropic and baroclinic instabilities, contributing 28.26 and 9.15 GW, respectively. Beyond directly supplying the barotropic pathway, mean kinetic energy also provides 11.55 GW of power to mean available potential energy and subsequently facilitates the baroclinic instability pathway.
2023 Funding Opportunity
CPO FY2023 Notice of Funding Opportunity
In 2014, NOAA’s Climate Program Office, led by Director Wayne Higgins, went through the process of rearticulating its mission, vision, and unique value through the development of the CPO Strategic Plan. The office also made major progress on an Implementation Plan that provides a roadmap to achieving important outcomes in climate science.
These accomplishments were just one of the highlights of a productive year for NOAA CPO, which continued to make advances in climate observation, research, modeling, and decision support activities for society. We also moved forward with global observations, advanced modeling and prediction capabilities, coastal resilience, drought monitoring and decision-support services, and so many other activities that will help people, businesses and ecosystems thrive in the face of climate and its impacts.
Princeton University, NOAA and eight other partner institutions now seek to make the Southern Ocean better known scientifically and publicly through a $21 million program that will create a biogeochemical and physical portrait of the ocean using hundreds of robotic floats deployed around Antarctica and an expanded computational capacity. The Southern Ocean Carbon and Climate Observations and Modeling program, or SOCCOM, is a six-year initiative headquartered at Princeton and funded by the National Science Foundation’s Division of Polar Programs, with additional support from the NOAA and NASA. The U.S. Argo program will play a major role in the project.
In mid-June, the Research Vessel Tangaroa, operated by New Zealand’s National Institute of Water and Atmospheric Research, set off from Wellington, New Zealand, for the Deep Argo Development cruise. The primary objectives of the cruise were (1) to deploy two prototype Deep Argo (6,000 meter plus) floats and (2) undertake deep (~5500m) CTD casts for sensor testing and development. In addition, 6 SOLO2 Argo (2,000 meter) floats were deployed in transit, finally, to make a "virtual field trip" for school uptake. The SOLO2 floats and the Deep Argo floats were provided by Scripps Institution of Oceanography as part of NOAA’s Argo Program.
NOAA’s Climate program Office continued to move forward with advancing modeling and prediction capabilities. Along with the National Centers for Environmental Prediction (NCEP), the office co-organized a topical collection of papers presented at a 2012 workshop held to evaluate progress in Climate Forecast System version 2 (CFSv2) performance. CFSv2 is a couple global climate model used to simulate intraseasonal-to-interannual climate variability. CPO sponsored research significantly contributed to the development of CFSv2. This collection of papers should provide insight for the development of the next generation CFS.
A report from the NOAA Drought Task Force, organized by the Modeling, Analysis, and Predictions, and projections (MAPP) Program of NOAA’s Climate Program Office, contributed to a growing field of science-climate attribution--where teams of scientists aim to identify the sources of observed climate and weather patterns. According to the study, natural oceanic and atmospheric patterns are the primary drivers behind California's ongoing drought. Further studies on these oceanic conditions and their effect on California's climate may lead to advances in drought early warning that can help water managers and major industries better prepare for lengthy dry spells in the future.
A paper published in the Journal for Atmospheric Chemistry and Physics quantified the performance of the Weather Research and Forecasting regional model with chemistry (WRF-Chem) in simulating the spatial and temporal variations in aerosol mass, composition, and size over California using the extensive meteorological, trace gas, and aerosol measurements collected during the California Nexus of Air Quality and Climate Experiment (CalNex) and the Carbonaceous Aerosol and Radiative Effects Study (CARES) conducted during May and June of 2010. The scientists concluded that the combined CalNex and CARES data sets are an ideal test bed that can be used to evaluate aerosol models in great detail and develop improved treatments for aerosol processes.
NOAA’s Climate Program Office played major roles in flagship climate programs, including the reauthorization of the National Integrated Drought Information System (NIDIS). On March 6, President Barack Obama signed the National Integrated Drought Information System Reauthorization Act into law in order to ensure that the federal government can provide timely, effective drought warning forecasts and vital support to communities that are vulnerable to drought. States, cities, towns, farmers, and businesses rely on tools and data from the National Integrated Drought Information System to make informed decisions about water use, crop planting, wildfire response, and other critical areas.
CPO’s funded scientists, projects, and program managers contributed to several major assessment reports released over the past year. Among these, the Arctic Research Program in the NOAA Climate Program Office supported the 2014 Arctic Report Card. The latest update confirmed that Arctic air temperatures continue to rise at more than twice the rate of the planet as a whole. Earlier in the year, NOAA and the American Meteorological Society released the 2013 State of the Climate report. The report, a 24-year tradition encompassing the work of 425 authors from 57 countries, uses dozens of climate indicators to track patterns, changes, and trends of the global climate system. Scientific research funded by CPO was also foundational to advancing the 2014 Third National Climate Assessment Report and the Intergovernmental Panel on Climate Change (IPCC) reports.
With 12,000 entries from all 50 US states and 60 plus countries and two millions votes in the Webby People’s Voice Awards, the 18th Annual Webby Awards was the biggest yet. NOAA Climate.gov was selected by the International Academy of the Digital Arts & Sciences to receive two Webby Awards in the "Government" and "Green" categories. The cross-agency team of world-class scientists, data visualizers, web developers, and science writers also garnered a People's Voice Award in the "Green" category (placing second overall in the "Government" category).
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