Was May abnormal this year?

The just completed month of May was quite unusual in southern Wisconsin this year.

First, it was a bit cooler than normal, with the average temperature ending up 0.6 degrees below normal. Dryness over central and western Canada brought large wildfires to those areas much earlier than normal this year, and the smoke from those fires gave us a number of orangey sunrises and sunsets this past month, which are more normal in July and August.

Statistics for May 2023 for Madison and Milwaukee, Wisconsin (Image credit: NOAA/NWS/MKX)

The dryness was widespread this May, in fact, as the Dane County Regional Airport totaled only 0.87 inches of rain in May, 3.23 inches below normal for the month. That is the predominant reason lawns around town are looking a bit yellow this early in the season — again, more like what we normally see in July and August.

Despite the relative coolness of the month as a whole, the temperature soared to 88 degrees on May 30, 91 degrees (our first of the season) on May 31, 89 degrees on June 1, 89 on June 2 and 91 on June 3. Were we just a bit warmer on three of those days, we would have set the earliest five-day streak of 90-degree days in Madison’s meteorological history. In fact, no five-day or longer such streak has ever had its origin in May.

Very recent events are the only close competitors, in fact. May 10-13 last year we had four straight days at 90 degrees or above (the earliest ever such streak) and from May 26 to 29, 2018, we also had a four-day streak. It had never happened before and almost happened again this year. Summer is certainly making itself known.

Steve Ackerman and Jonathan Martin, professors in the UW-Madison department of atmospheric and oceanic sciences, are guests on WHA radio (970 AM) at 11:45 a.m. the last Monday of each month. Send them your questions at stevea@ssec.wisc.edu or jemarti1@wisc.edu.

Category: Climate, Meteorology, Seasons

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Are the number of thunderstorms in Wisconsin decreasing?

This question comes from one of our readers, based on casual observation. It is always good to get data and analyze such a generalization to find the best answer. So, we turned to the Wisconsin State Climatology Office.

The National Weather Service records the number of thunderstorm days at several sites across the U.S. A thunderstorm day is when thunder or lightning is detected at least once during the day. Since the mid-1990s, the nation’s primary surface weather observation network is the Automated Surface Observing Systems, or ASOS program, which has essentially replaced human observers.

NWS thunderstorm categories.

ASOS is a joint effort of the National Weather Service, the Federal Aviation Administration and the Department of Defense. These automated weather stations routinely measure temperature, humidity, winds, visibility and precipitation. Some ASOS sites also have a single-site lightning sensor. We can detect lightning by observing an optical flash or an electrical field change. If lightning is detected, a thunderstorm is in the area.

Additionally, two different networks in the United States — the National Lightning Detection Network and the Earth Networks Total Lightning Network — also detect lightning flashes. These two systems work by detecting radio waves generated by lightning strokes. Since 2016, a Geostationary Lightning Mapper instrument has flown on two weather satellites that map total lightning activity.

An analysis of the annual number of thunderstorm days at the Dane County Regional Airport in Madison shows no obvious trend, although the average number of thunderstorm days between 1990 and 2020 is a bit smaller than during the 30-year period of 1950-1980. An analysis of the number of thunderstorms in Green Bay and La Crosse does show a gradual decline in thunderstorm days. There are no upward trends in the number of thunderstorm days at these sites.

Steve Ackerman and Jonathan Martin, professors in the UW-Madison department of atmospheric and oceanic sciences, are guests on WHA radio (970 AM) at 11:45 a.m. the last Monday of each month. Send them your questions at stevea@ssec.wisc.edu or jemarti1@wisc.edu.

Category: Climate, Meteorology, Severe Weather

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Why was the sun so red this past week?

Light is a form of electromagnetic energy that does not need matter to propagate. We can characterize this energy by its wavelength, which is the distance along a wave from one crest to another. Our eyes are sensitive to light with wavelengths between approximately 0.4 to 0.7 microns. Blue colors have shorter wavelengths, while red colors have longer ones.

When light interacts with particles suspended in air, it can be scattered or absorbed. Energy that is scattered causes a change in direction of the light path. The amount of light that is being scattered is a function of the size of the particle relative to the wavelength of the light falling on the particle. While all colors are scattered by air molecules, violet and blue are scattered most. The sky looks blue, not violet, because our eyes are more sensitive to blue light.

Wisconsin sunrise on May 22nd. Credit: Amy Larson

This past week, upper-level winds carried smoke from fires in western Canada over the Midwest. Smoke can cause the sky to appear hazy, even if the smoke is high above the ground. When smoke is thick, it can cause brilliant red sunsets and sunrises. Small smoke particles scatter blue light. So, as the sun sets or rises and its rays pass through the smoke plume, all the blue lights are scattered out of the path between the setting sun and your eyes, leaving only the red and orange colors. This results in the sun having a bright red color.

If the winds are right, the smoke can be transported down to the ground. This can cause a reduction in air quality. The small particles that make up the smoke can cause respiratory problems, particularly for children, the elderly, and people with asthma.

Steve Ackerman and Jonathan Martin, professors in the UW-Madison department of atmospheric and oceanic sciences, are guests on WHA radio (970 AM) at 11:45 a.m. the last Monday of each month. Send them your questions at stevea@ssec.wisc.edu or jemarti1@wisc.edu.

 
Category: Meteorology, Phenomena, Weather Dangers

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Can record high and low temperatures help define regional definitions of seasons?

Though it now seems to be fully in swing, the spring has sure seemed delayed in coming this year in southern Wisconsin. This made us wonder if there might be a more refined, and local, way to think about the calendar-day boundaries of the seasons.

In research undertaken to write a recent column, we catalogued Madison’s record high and low temperature data for each calendar day employing data that went back to 1939. An interesting partition of the full year resulted from this simple analysis.

It turns out that not once over these past 83 years has a daily record low temperature been 32 degrees or lower between June 11 and Sept. 11. Might this be a valid reason to suggest summer in Madison extends from June 11 through Sept. 11?

On the other extreme, at least once over these last 83 years, a record low has been zero or below on every day from Nov. 23 to March 15. Might this be a valid reason to suggest that winter in Madison extends from Nov. 23 to March 15?

Once these notions are entertained, they really start to make intuitive sense. Of course, then “spring” in Madison would extend from March 16 to June 10 (again, roughly consistent with a native’s impression), and “autumn” would extend from Sept. 12 to Nov. 22.

2023 Daily Temperatures for Madison bounded by historical averages.
Credit: Wisconsin State Climatology Office

There may be more sophisticated ways to characterize the seasons locally, but using just two seemingly arbitrary temperature thresholds as we’ve done here returns a fairly satisfactory result.

Steve Ackerman and Jonathan Martin, professors in the UW-Madison department of atmospheric and oceanic sciences, are guests on WHA radio (970 AM) at 11:45 a.m. the last Monday of each month. Send them your questions at stevea@ssec.wisc.edu or jemarti1@wisc.edu.

Category: Climate, Meteorology, Seasons

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What are gravity waves?

In a gravity wave, the upward moving region is the most favorable region for cloud development and the sinking region favorable for clear skies. That is why you may see rows of clouds and clear areas between the rows of clouds. A gravity wave is nothing more than a wave moving through a stable layer of the atmosphere.  (Image credit: NOAA)

Picture a rock thrown into a lake on a calm day. That is an excellent example of what a gravity wave looks like.

Ripples migrate from where the rock hits the water, causing an up and down motion along the water’s surface. As we get farther away from the point where the rock hit the water, the waves dampen, becoming less defined.

These ripples, or waves, travel along a stable boundary between the water surface and the air above. Gravity waves also occur along stable layers but in the atmosphere.

To understand how gravity waves form, imagine a small volume of air, large enough to contain a very great number of molecules, but small enough so that the properties assigned to it are approximately uniform. In a stable atmosphere, if an air parcel is forced to rise or sink, the parcel will tend to return to its original position. If the air parcel ins in an unstable atmosphere, it will accelerate away from its initial position after being pushed. Atmospheric gravity waves form in stable air when parcels are forced upward and gravity pulls it back down.

As with the stone thrown in a pond, to start a gravity wave in the atmosphere, we need a perturbation to displace an air parcel in the vertical. Flow over mountains and thunderstorm updrafts are good examples of trigger mechanisms. An upward moving parcel expands and cools, making favorable condition for cloud development. A downward moving parcel is compressed and warms, lowering the humidity.

Gravity waves in the atmosphere sometimes appear as rows of clouds between rows of clear area. The upward moving region is the most favorable region for cloud development and the sinking region favorable for clear skies.

Steve Ackerman and Jonathan Martin, professors in the UW-Madison department of atmospheric and oceanic sciences, are guests on WHA radio (970 AM) at 11:45 a.m. the last Monday of each month. Send them your questions at stevea@ssec.wisc.edu or jemarti1@wisc.edu.

Category: Meteorology, Phenomena

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