Publikationsdatum:
2022-05-26
Beschreibung:
Author Posting. © The Oceanography Society, 2017. This article is posted here by permission of The Oceanography Society for personal use, not for redistribution. The definitive version was published in Oceanography 30, no. 2 (2017): 92–103, doi:10.5670/oceanog.2017.227.
Beschreibung:
The tropical Atlantic basin is one of seven global regions where tropical cyclones (TCs) commonly originate, intensify, and affect highly populated coastal areas. Under appropriate atmospheric conditions, TC intensification can be linked to upper-ocean properties. Errors in Atlantic TC intensification forecasts have not been significantly reduced during the last 25 years. The combined use of in situ and satellite observations, particularly of temperature and salinity ahead of TCs, has the potential to improve the representation of the ocean, more accurately initialize hurricane intensity forecast models, and identify areas where TCs may intensify. However, a sustained in situ ocean observing system in the tropical North Atlantic Ocean and Caribbean Sea dedicated to measuring subsurface temperature, salinity, and density fields in support of TC intensity studies and forecasts has yet to be designed and implemented. Autonomous and Lagrangian platforms and sensors offer cost-effective opportunities to accomplish this objective. Here, we highlight recent efforts to use autonomous platforms and sensors, including surface drifters, profiling floats, underwater gliders, and dropsondes, to better understand air-sea processes during high-wind events, particularly those geared toward improving hurricane intensity forecasts. Real-time data availability is key for assimilation into numerical weather forecast models.
Beschreibung:
The NOAA/AOML component of this work was originally
funded by the Disaster Relief Appropriations
Act of 2013, also known as the Sandy Supplemental,
and is currently funded through NOAA research
grant NA14OAR4830103 by AOML and CARICOOS,
as well as NOAA’s Integrated Ocean Observing
System (IOOS). The TEMPESTS component of
this work is supported by NOAA through the
Cooperative Institute for the North Atlantic Region
(NA13OAR4830233) with additional analysis support
from the WHOI Summer Student Fellowship
Program, Nortek Student Equipment Grant, and
the Rutgers University Teledyne Webb Graduate
Student Fellowship Program. The drifter component
of this work is funded through NOAA grant
NA15OAR4320071(11.432) in support of the Global
Drifter Program.
Repository-Name:
Woods Hole Open Access Server
Materialart:
Article
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