We’ve written often about hurricanes, great and small. Of note, forecasters predict a 70-percent likelihood of 11 to 17 named storms (winds of 39 mph or higher), of which five to nine could become hurricanes (winds of 74 mph or higher), including two to four major hurricanes (Category 3, 4 or 5; winds of 111 mph or higher) for this season. An average season produces 12 named storms of which six become hurricanes, including three major hurricanes.
The 2016 season was the most active since 2012, with 15 named storms, including seven hurricanes and four major hurricanes. Last year was even worse.
This column is about rip tides, rip currents and undertows — which are what distant storms often leave us — lest one of us comes to grief . . .
Undertow vs. Rip Tide vs. Rip Currents
Anybody that has ever been to a beach understands undertow. It is the backwash as gravity returns a breaking wave to the sea. All but small children can stand against it — and its effect ends at the leading edge of the next breaking wave. While it might knock you down and thus “suck” you under, it won’t pull you out to sea. Our mothers didn’t know that because they confused undertow with rip tides and rip currents.
A rip tide is the result of tides and the egress and ingress of large volumes of water flowing through inlets, estuaries, and bays. As facts would have it, most people don’t swim near inlets or where bays meet the sea. They swim near beaches, where sand bars often form, and where rip currents, “the killer current,” form in concert.
The Anatomy of a Rip Current
Rip currents are by far the biggest killers of ocean swimmers. Rip currents form as waves disperse along the beach, causing water to become trapped between the beach and a sandbar or other underwater feature. This water becomes the “feeder” that creates the deadly force of the rip current. The water converges into a narrow, river-like channel moving away from the shore at high speed.
Marine scientists define a rip current as having a “neck” (the river-like channel moving away from the shore) and a “head” that is often defined by an unusual disturbance or choppiness in the water and by murky discoloration caused by sand and debris. As the water, and swimmer, reaches the head the velocity and strength of the rip current circulation begins to weaken considerably.
Can I See a Rip Current?
Often, yes. As a result of the current’s speed, sand is forced into suspension often causing a rip current to be associated with “dirty” water. It is characterized by a strong, localized current flowing seaward from the shore, visible as an agitated band of water, which is the return movement of water piled up on the shore by incoming waves.
Most Importantly, Can I Get Out of the Grip of a Rip Current?
If you don’t panic, and play the water’s power to your advantage, yes. Don’t try to swim back to shore against the rip current that is dragging you out. Most likely, you will tire beyond recovery and drowning, flatly put, will follow as surely as night follows day. Swim with and across the rip current. Let it give you some speed — as you “exit — stage left!” Or right — but get out of the grip of the current and into “normal” water. Then, deal with the hand you’ve been dealt — swim back, or just tread water while waving your arms for help, or just float and rest. This is why swimming with a “buddy system” is so critical.
BTW, if you are interested in being part of USCG Forces, email me at JoinUSCGAux@aol.com or go direct to the D1SR Human Resources Department. The folks there are in charge of new members matters will help you “get in this thing . . .”