In late January and early February 2026, surges of Arctic air funneled into eastern North America, causing cold and wintry conditions across much of the United States. Snow and ice blanketed large swaths<\/a> of the country, stretching as far south as Georgia<\/a>, in a layer of white. Meanwhile, waters off the west coast of Florida lit up in brilliant shades of blue.<\/p>\n In this rare outbreak of intense winter weather, cold air infiltrated Florida and drove temperatures below freezing in several counties<\/a> at the start of February. This frigid intrusion not only caused beautiful phenomena in the atmosphere, forming cloud streets<\/a>, but it also produced a colorful display in the shallow marine waters below, stirring up carbonate sediment from the seafloor.<\/p>\n On February 3, the\u00a0MODIS<\/a>\u00a0(Moderate Resolution Imaging Spectroradiometer) on NASA\u2019s\u00a0Terra<\/a>\u00a0satellite captured this image (right) of brightened waters over the West Florida Shelf, a broad and shallow continental shelf region known as a carbonate ramp<\/a>. The blue color comes from suspended calcium carbonate (CaCO3<\/sub>) mud, which consists primarily of remnants of marine organisms that live on the shelf. For comparison, the left image shows the area on January 24, before the cold air arrived.<\/p>\n The mud was mostly kicked up by wind-stirred ocean waters during the cold air event, said James Acker, a data support scientist at the NASA Goddard Earth Sciences Data and Information Services Center. Sediment suspension events like this are more typically associated with hurricane winds that churn the water, as with Melissa in 2025<\/a>, but the winds brought by strong cold fronts can have a similar, if less dramatic, effect.<\/p>\n \u201cAnother interesting aspect of these events is that the cold air cools off the shallow water on the banks and makes it denser than the surrounding warmer open ocean water,\u201d Acker said. When this dense water sinks and flows offshore with the tides, it can carry some of the sediment out toward the shelf\u2019s edge.<\/p>\n The detailed images above, acquired with the OLI<\/a>\u00a0(Operational Land Imager) on\u00a0Landsat 9<\/a>, offer a closer look at that process playing out. \u201cHammerhead\u201d eddy features appeared along the slope of the West Florida Shelf, Acker noted. These can form when narrow streams of denser chilled seawater carry sediment offshore, encounter slower-moving Gulf waters, and curl into pairs of counterrotating eddies, he said. These types of features have been observed in other natural events\u2014dust storms<\/a>, for example\u2014both on Earth and on Mars.<\/p>\n Other dynamics were at work near the Dry Tortugas on the southwestern side of the shelf, where the patch of bright water ends abruptly along a straight, sharp edge. Here, sediment-laden water exited the shelf area through channels to the south, said sedimentologist\u00a0Jude Wilber<\/a>, and was immediately swept east by the Loop Current<\/a>. After Hurricane Ian stirred up sediment<\/a> off Florida in 2022, Wilber and Acker noted a similar interaction between suspended material and the Loop Current. The researchers used that event to improve satellite-based methods for estimating sediment concentrations<\/a> in these plumes.<\/p>\n Scientists are interested in studying carbonate sediment suspension events because of their role in the planet\u2019s\u00a0carbon cycle<\/a>. They have shown that tropical cyclones are the primary mechanism<\/a> by which carbon in shallow-water marine sediments is moved to deeper waters, where it can remain sequestered for a long time. However, the contribution of cold fronts is less well understood. Acker and Wilber hypothesize that they act on a more local scale: they influence ocean color by stirring sediments but do not transport significant amounts of material to the deep ocean.<\/p>\n NASA Earth Observatory images by Michala Garrison, using MODIS data from NASA\u00a0<\/em>EOSDIS LANCE<\/em><\/a>\u00a0and\u00a0GIBS\/Worldview<\/a>, and Landsat data from the\u00a0<\/em>U.S. Geological Survey<\/em><\/a>.<\/em> Story by Lindsey Doermann.<\/em><\/p>\n![\"Gulf](\"https:\/\/assets.science.nasa.gov\/dynamicimage\/assets\/science\/esd\/eo\/images\/iotd\/2026\/arctic-blast-brightened-the-west-florida-shelf\/floridaupwelling_tmo_20260124_lrg.jpg?w=2160&h=1640&fit=clip&crop=faces%2Cfocalpoint\")
<\/figure>\n<\/div><\/div><\/div>\n![\"Gulf](\"https:\/\/assets.science.nasa.gov\/dynamicimage\/assets\/science\/esd\/eo\/images\/iotd\/2026\/arctic-blast-brightened-the-west-florida-shelf\/floridaupwelling_tmo_20260203_lrg.jpg?w=2160&h=1640&fit=clip&crop=faces%2Cfocalpoint\")
<\/figure>\n<\/div><\/div><\/div>\n![\"The](\"https:\/\/assets.science.nasa.gov\/dynamicimage\/assets\/science\/esd\/eo\/images\/iotd\/2026\/arctic-blast-brightened-the-west-florida-shelf\/florida_oli2_20260203_lrg.jpg?w=5315&h=4148&fit=clip&crop=faces%2Cfocalpoint\")
<\/figure>\n<\/div><\/div>\nLandsat, February 3, 2026<\/h2>\n<\/p><\/div><\/div>\n
![\"An](\"https:\/\/assets.science.nasa.gov\/dynamicimage\/assets\/science\/esd\/eo\/images\/iotd\/2026\/arctic-blast-brightened-the-west-florida-shelf\/floridawave_oli2_20260203_lrg.jpg?w=1171&h=976&fit=clip&crop=faces%2Cfocalpoint\")
<\/figure>\n<\/div><\/div>\nLandsat, February 3, 2026<\/h2>\n<\/p><\/div><\/div><\/div><\/div>\n
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