Today’s info is on the wind, weather and ocean currents.
Coastal currents are affected by local winds. Surface ocean currents, which occur on the open ocean, are driven by a complex global wind system. To understand the effects of winds on ocean currents, one first needs to understand the Coriolis force and the Ekman spiral.
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Trade Winds
In the Northern Hemisphere, warm air around the equator rises and flows north toward the pole. As the air moves away from the equator, the Coriolis effect deflects it toward the right. It cools and descends near 30 degrees North latitude. The descending air blows from the northeast to the southwest, back toward the equator (Ross, 1995). A similar wind pattern occurs in the Southern Hemisphere; these winds blow from the southeast toward the northwest and descend near 30 degrees South latitude.
These prevailing winds, known as the trade winds, meet at the Intertropical Convergence Zone (also called the doldrums) between 5 degrees North and 5 degrees South latitude, where the winds are calm. The remaining air (air that does not descend at 30 degrees North or South latitude) continues toward the poles and is known as the westerly winds, or westerlies. The trade winds are so named because ships have historically taken advantage of them to aid their journies between Europe and the Americas (Bowditch, 1995).
Global winds drag on the water’s surface, causing it to move and build up in the direction that the wind is blowing. And just as the Coriolis effect deflects winds to the right in the Northern Hemisphere and to the left in the Southern Hemisphere, it also results in the deflection of major surface ocean currents to the right in the Northern Hemisphere (in a clockwise spiral) and to the left in the Southern Hemisphere (in a counter-clockwise spiral). These major spirals of ocean-circling currents are called “gyres” and occur north and south of the equator. They do not occur at the equator, where the Coriolis effect is not present (Ross, 1995).
There are five major ocean-wide gyres—the North Atlantic, South Atlantic, North Pacific, South Pacific, and Indian Ocean gyres. Each is flanked by a strong and narrow “western boundary current,” and a weak and broad “eastern boundary current” (Ross, 1995).
One particularly powerful western boundary current is the Gulf Stream. The Gulf Stream, paired with the eastern boundary Canary Current, flanks the North Atlantic gyre. The Gulf Stream, also called the North Atlantic Drift, originates in the Gulf of Mexico, exits through the Strait of Florida, and follows the eastern coastline of the United States and Newfoundland. It travels at speeds of 25 to 75 miles per day at about one to three knots (1.15-3.45 miles per hour or 1.85-5.55 kilometers per hour). It influences the climate of the east coast of Florida, keeping temperatures warmer in the winter and cooler than the other southeastern states in the summer. Since it also extends toward Europe, it warms western European countries as well.
The Ekman spiral, named after Swedish scientist Vagn Walfrid Ekman (1874-1954) who first theorized it in 1902, is a consequence of the Coriolis effect. When surface water molecules move by the force of the wind, they, in turn, drag deeper layers of water molecules below them. Each layer of water molecules is moved by friction from the shallower layer, and each deeper layer moves more slowly than the layer above it, until the movement ceases at a depth of about 100 meters (330 feet). Like the surface water, however, the deeper water is deflected by the Coriolis effect—to the right in the Northern Hemisphere and to the left in the Southern Hemisphere. As a result, each successively deeper layer of water moves more slowly to the right or left, creating a spiral effect. Because the deeper layers of water move more slowly than the shallower layers, they tend to “twist around” and flow opposite to the surface current.
Wind shear, sometimes referred to as wind gradient, is a difference in wind speed and direction over a relatively short distance in the Earth’s atmosphere. Wind shear can be broken down into vertical and horizontal components, with horizontal wind shear seen across weather fronts and near the coast, and vertical shear typically near the surface,though also at higher levels in the atmosphere near upper level jets and frontal zones aloft.
Wind shear itself is a microscale meteorological phenomenon occurring over a very small distance, but it can be associated with mesoscale or synoptic scale weather features such as squall lines and cold fronts. It is commonly observed near microbursts and downbursts caused by thunderstorms, weather fronts, areas of locally higher low level winds referred to as low level jets, near mountains, radiation inversions that occur because of clear skies and calm winds, buildings, wind turbines, and sailboats. Wind shear has a significant effect on the control of aircraft during take-off and landing, and was a significant cause of aircraft accidents involving large loss of life within the United States.
Sound movement through the atmosphere is affected by wind shear, which can bend the wave front, causing sounds to be heard where they normally would not, or vice versa. Strong vertical wind shear within the troposphere also inhibits tropical cyclone development, but helps to organize individual thunderstorms into living longer life cycles that can then produce severe weather. The thermal wind concept explains how differences in wind speed with height are dependent on horizontal temperature differences, and explains the existence of the jet stream.
Today’s Forecast
Thunderstorms with locally heavy rain…gusty winds and cloud to ground lightning strikes are possible today mainly to the southeast of a Holland to Mount Pleasant line. Scattered power outages could occur. The risk for rain heavy at times could persist into tonight…mainly towards the Jackson region. Ponding of the water and poor drainage flooding could occur.
Here is the 0500 Chicago (KLOT) radar.
….and here is the current radar….
It is cooler out there tonight than it was last night. Once we get thru Friday the weekend looks awesome!! Sunny and a little warmer. Next week looks great too.
Today is just another typical below normal temp day as will be the case tomorrow and Saturday with plenty of clouds! Incredible!
Well not according to this:
https://forecast.weather.gov/product.php?site=grr&product=cli&issuedby=grr
Shows today was actually above normal for the 3rd or 4th day in a row.
If you like cool temps, rain and wet grounds this weather is perfect! This has been a horrible Spring so far. Snow, wind, cool temps, clouds, rain, fog and soggy grounds! I am sure it is great for Barry and Andy however! incredible!
Not sure why you’re so fascinated by what I do outside, but have at it I guess. This week the ground has been wet, but the previous several weeks it was so dry Zeeland Township actual had burn bans and fire warnings out. Of course I’m always kept up to date as my wife works there.
http://www.zeelandtwp.org/
40’s Friday and Saturday with rain..How many days to May? Daughter #2 has a Lacrosse game tonight should be wonderful weather standing in the cool rain so much for the grill tonight ….INDY!
That’s okay. It’s always a bit cooler following a cold front. The most important day, Easter Sunday, will be fantastic.
Yes Easter egg hunt should take off well with sunshine …INDY
👍
With out the gulf stream Europe would be much colder in the winter time then it is now, Grand Rapids, Holland and Muskegon had backward maximums for today. The high at Holland and Muskegon will be 68 and that occurred at 2 AM and at Grand Rapids the maximum was 64 at 7 AM the temperatures went up during the nighttime hours and now are going down after day light.
Slim
Yesterday Barry asked how many months have been above or below average in the past. Well so far I went back thru 2014. The annual mean for the 5 years 4 were above average and one was below average. The mean average annual mean for Grand Rapids is 48.1° for the past years 2018 mean 49.6, 2017 50.3, 2016 51.2, 2015 48.9 and 2014 46.5° Now for a year by year break down note I have included 2019 in this as well. For 2019 all 3 months so far this year are below average for 2018. 8 were above and 4 were below. 2017, 6 were above and 5 were below and one was average. For 2016 10 were above and 2 were below. For 2015 5 were above and 7 were below for 2014 4 were above and 8 were below. Of the 63 months in this time period 33 months were above 29 were below and one was average. Remember this is for the Grand Rapids location only. I think I will do more on this subject for some Saturday post. But will let you know that going back to 2000 14 years have been warmer then average at GR
Slim
Thanks for clearing that up Slim! You are the boss at weather stats! I had guessed that over the past 4 or 5 years we had been in an above normal pattern, and this confirms it. Hopefully the Rock guy/gal reads this as well and now we can end our disagreement.
It sure has been windy this Spring …Im thinking about my grill this afternoon with some Sprites this could be the perfect Spring delight. Have a super day…INDY!
Anyone that complains that the weatherman was wrong, has no idea how complex and complicated forecasting really is. So many factors to consider Case in point – this post. When you consider the global scale of the winds, it’s incredible that meteorologists are able to forecast a storm many days in advance when the storm is 1000s of miles away out in the Pacific.
GR is back above average for April with the long term forecasts showing warmth! We are entrenched in a long term warm pattern.
In the last 63 months (going back to the start of 2014) 33 months have been above average and 29 have been below average one has been average. for the annual mean of the past 5 years 4 have been above average and one below average.
Slim
Including 3 or 4 warm years in a row!
Forget all of these clouds and rain, let’s see some sun and 70degrees!