A typical weather system, which was producing stormy weather off the coast of Florida early Friday, could reach tropical storm strength, earning the name Ophelia before striking the Carolinas and moving through the Mid-Atlantic States this weekend.
Nearly seven million people in the Carolinas and the Mid-Atlantic region were under tropical storm warnings as of 2 a.m. on Friday morning, according to the National Weather Service.
The National Hurricane Center estimated that the storm, currently called Potential Tropical Cyclone 16, had sustained winds of about 40 miles per hour. Tropical disturbances are typically named when they have sustained winds of 39 m.p.h. Once winds reach 74 m.p.h., a storm becomes a hurricane; at 111 m.p.h., it becomes a major hurricane.
Forecasters with the Hurricane Center believe the storm system that could become Ophelia will continue to gain strength Thursday into Friday. Tropical storm warnings were in effect early Friday from Cape Fear, N.C., north to Fenwick Island, Del. They were also in effect for Albemarle Sound and Pamlico Sound in North Carolina, as well as for some coastal areas of Maryland.
Just last weekend, Lee produced tropical-storm conditions in New England as it made landfall in Canada. This weekend, similar tropical-storm-force winds and some coastal flooding from storm surge are possible in the Carolinas and Virginia. Heavy rain could produce some minor flooding across the eastern Mid-Atlantic States from North Carolina to New Jersey from Friday through Sunday.
When it earns a name, it will most likely be considered a subtropical storm first. This is common when a typical weather system, which gets its energy from competing cold and warm air masses, begins to transition into a tropical cyclone that pulls energy from warm ocean temperatures. Forecasters believe the core of the storm will probably have become fully tropical when it reaches North Carolina’s coast Saturday morning. This means the stronger winds could probably be found closer to the storm’s center.
It’s possible for this storm to have a smaller-scale tropical cyclone embedded within the larger envelope of a nontropical system, Daniel Brown, a senior specialist at the Hurricane Center, said.
The Atlantic hurricane season started on June 1 and runs through Nov. 30.
In late May, the National Oceanic and Atmospheric Administration predicted that there would be 12 to 17 named storms this year, a “near-normal” amount. On Aug. 10, NOAA officials revised their estimate upward, to 14 to 21 storms.
There were 14 named storms last year, after two extremely busy Atlantic hurricane seasons in which forecasters ran out of names and had to resort to backup lists. (A record 30 named storms took place in 2020.)
This year features an El Niño pattern, which arrived in June. The intermittent climate phenomenon can have wide-ranging effects on weather around the world, and it typically impedes the number of Atlantic hurricanes.
In the Atlantic, El Niño increases the amount of wind shear, or the change in wind speed and direction from the ocean or land surface into the atmosphere. Hurricanes need a calm environment to form, and the instability caused by increased wind shear makes those conditions less likely. (El Niño has the opposite effect in the Pacific, reducing the amount of wind shear.)
At the same time, this year’s heightened sea surface temperatures pose a number of threats, including the ability to supercharge storms.
That unusual confluence of factors has made solid storm predictions more difficult.
“Stuff just doesn’t feel right,” Phil Klotzbach, a hurricane researcher at Colorado State University, said after NOAA released its updated forecast in August. “There’s just a lot of kind of screwy things that we haven’t seen before.”
There is solid consensus among scientists that hurricanes are becoming more powerful because of climate change. Although there might not be more named storms overall, the likelihood of major hurricanes is increasing.
Climate change is also affecting the amount of rain that storms can produce. In a warming world, the air can hold more moisture, which means a named storm can hold and produce more rainfall, like Hurricane Harvey did in Texas in 2017, when some areas received more than 40 inches of rain in less than 48 hours.
Researchers have also found that storms have slowed down, sitting over areas for longer, over the past few decades.
When a storm slows down over water, the amount of moisture the storm can absorb increases. When the storm slows over land, the amount of rain that falls over a single location increases; in 2019, for example, Hurricane Dorian slowed to a crawl over the northwestern Bahamas, resulting in a total rainfall of 22.84 inches in Hope Town during the storm.