How do you measure how hot the summer is?

Posted on June 13, 2016 by WeatherGuys Editor
Jennifer Ronquillo, of Madison, plays with her daughters, Sienna, 3, and Neaveh, 1, at bottom, at Goodman Pool on opening day, Friday, Madison's first 90-degree day of the year.

Jennifer Ronquillo, of Madison, plays with her daughters, Sienna, 3, and Neaveh, 1, at bottom, at Goodman Pool on opening day, Friday, Madison’s first 90-degree day of the year.

After experiencing our first 90-degree day of the season on Friday, many people are wondering what we might expect this summer.

It turns out that the number or 90-degree days each summer is extremely variable here in Madison. From 1971 to 2015, the average number of days at or above 90 in Madison was 10.96. This average, however, struggles to convey a sense of the variability.

A better way to express that variability is by calculating the standard deviation, which, when added to or subtracted from the average, sets a range in which approximately two-thirds of the years will fall.

In this case the standard deviation is nine. Thus, we might expect that two-thirds of the years would range from having 20 to two days at or above 90. As it turns out, 33 of the last 45 summers have been in that range.

It  is interesting that six summers have had 20 or more hot days (1975, 1976, 1983, 1988, 1995 and 2012) – the record being held by 2012 with 39 days.

Over the last four and a half decades, there has been a trend toward fewer hot days each summer, with the averages being 15.8, 11.7, 8.2 and 7.3 days for the 1970s, ’80s, ’90s and ’00s, respectively. The half-completed 2010s, by virtue of the incredibly warm 2012, appear to be bucking this trend as, thus far, we have averaged 12 such days each summer in this decade, though only 2012 had as many as 12.

It remains to be seen what the rest of this summer and the decade will bring, but these data remind us how complicated the interplay between weather and climate can be since the global average temperature has been trending the other way in these same decades.

Category: Climate, Meteorology, Seasons

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What is the prediction for this year’s hurricane season?

Posted on June 6, 2016 by WeatherGuys Editor
This photo, taken from video provided by NASA, shows Hurricane Alex -- a rare January hurricane in the Atlantic -- seen from the International Space Station. The National Oceanic and Atmospheric Administration (NOAA) is predicting 10-16 named storms this hurricane season, which runs from June through November in the Atlantic Ocean basin. (Photo credit: NASA)

This photo, taken from video provided by NASA, shows Hurricane Alex — a rare January hurricane in the Atlantic — seen from the International Space Station. The National Oceanic and Atmospheric Administration (NOAA) is predicting 10-16 named storms this hurricane season, which runs from June through November in the Atlantic Ocean basin. (Photo credit: NASA)

Hurricane season in the Atlantic Ocean basin runs from June through November.

 

The National Oceanic and Atmospheric Administration (NOAA) is predicting 10 to 16 named storms this season.

To acquire a name, the storm must have wind speeds of 39 mph or higher. Of these, four to eight will turn into hurricanes; one to four of these storms are predicted to become major hurricanes with sustained winds of at least 111 miles per hour.

NOAA does not make a seasonal prediction on the path of hurricanes but will predict a hurricane’s path once the storm develops.

On average, the Atlantic Ocean sees 12 named storms, six hurricanes and three major hurricanes. So, if the forecast holds, we are in for an average hurricane season.

The last three years have seen weaker hurricane season, so this year may see high activity.

The forecast is based on current and expected conditions. First, an active season would be predicted if the sea surface temperatures are warmer than normal. Warmer temperatures increase evaporation off the sea surface and that provides the energy for the storm.

We are coming out of an El Niño year and there is a 70 percent chance entering a La Niña, a condition that favors more hurricane activity than average.

Perhaps surprisingly, the atmospheric pressure pattern over the Arctic also plays a role in the forecast: high pressure means a weaker jet stream, which favors hurricane development.

We already have had Hurricane Alex, which occurred in mid-January of this year. Hurricanes can exist outside of the defined hurricane season. Tropical Storm Bonnie was a weak but persistent tropical storm that formed on May 27.

Category: Severe Weather, Tropical

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What can be learned from the recurrence of extreme weather events?

Posted on June 2, 2016 by WeatherGuys Editor
Roberto Salas, left, and Lewis Sternhagen check a flooded car in Houston on May 26. This spring the Houston area has experienced five separate rain events that have been classified as "once in a hundred year" events, which have a 1 percent chance (or a 1-in-a -100 chance) of occurring in any given year. (Photo credit: Associated Press)

Roberto Salas, left, and Lewis Sternhagen check a flooded car in Houston on May 26. This spring the Houston area has experienced five separate rain events that have been classified as “once in a hundred year” events, which have a 1 percent chance (or a 1-in-a -100 chance) of occurring in any given year. (Photo credit: Associated Press)

In 2004, the Boston Red Sox won the World Series for the first time in 86 years and their loyal fans were ecstatic. In the very next year, the Chicago White Sox won their first World Series title in 88 years.

Never in the long history of baseball had two teams that had been denied championships for so long won those long-coveted titles in successive years. This circumstance was at least partially a function of the changes in baseball brought about by free agency — a fundamental change to the rules.

This spring the Houston area has experienced five separate rain events that have been classified as “once in a hundred year” events. A 100-year event has a 1 percent chance (or 1-in-a-100 chance) of occurring in any given year.

This designation is meant to suggest that the intensity of these events is not likely to return to Houston except every 100 years or so. Thus, to have experienced five such storms in a single season is extremely unlikely and points toward an alteration in the climate (a fundamental change in the “rules”) of the region.

In a similar way, readers might recall that here in Madison in March 2012 we recorded five days with temperatures at or above 80 degrees. In the prior 100 years, only five other March days had ever topped 80 degrees, so that was also exceptionally unusual and provided evidence also suggestive of a shift in the climate toward a warmer world.

As isolated incidents, these meteorological phenomena can be expected every so often even in an unchanging climate as there is a lot of internal variability in the atmosphere.

In the seemingly recurring sequence we have experienced in the past couple of decades, however, there is little doubt that such events are among the fingerprints of a changing climate — a reality that we simply must confront in a coordinated, scientifically informed manner. A great number of dedicated scientists at UW-Madison are actively seeking better understanding of the complicated weather/climate system.

Category: Climate, Meteorology, Severe Weather

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How will a warmer planet affect the severity of mid-latitude storms?

Posted on May 23, 2016 by WeatherGuys Editor
Motorists and a fire engine brave high water on East Washington Avenue between the cross streets of Blount and Livingston Streets after a strong storm dumped large amounts of rain in Madison on June 30, 2014. Storms in the warmer, moister atmosphere of the future have the potential to be more severe than otherwise similar storms today. (Photo credit: M. P. King, State Journal archives)

Motorists and a fire engine brave high water on East Washington Avenue between the cross streets of Blount and Livingston Streets after a strong storm dumped large amounts of rain in Madison on June 30, 2014. Storms in the warmer, moister atmosphere of the future have the potential to be more severe than otherwise similar storms today. (Photo credit: M. P. King, State Journal archives)

In an individual storm, the release of latent heat results in stronger updrafts of air (which form the precipitation) and in stronger winds associated with the storm.

One of the consequences of the gradual global warming that is currently occurring is that more water vapor finds its way into the atmosphere when the temperature rises.

As the temperature continues to warm, even more water vapor will reside in the atmosphere. Thus, storms in the warmer, moister atmosphere of the future have the potential to be more severe than otherwise similar storms today.

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Though the storms themselves develop in response to their large-scale environments, their development also directly impacts those environments in ways that are not yet well understood.

Especially unknown is the way in which the more abundant moisture of a warmer atmosphere will help shape the large-scale environments of the future.

Some studies suggest that the overall number of storms may decrease but that particularly severe storms may become more frequent.

Still others suggest no increase in the number of severe storms.

One thing seems certain: As the planet continues to warm, increases in the water vapor content of the atmosphere will likely change the frequency and distribution of mid-latitude storms and our agricultural and transportation infrastructure will have to adapt to those changes.

Category: Climate, Meteorology, Severe Weather

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What is the hydrologic cycle?

Posted on May 16, 2016 by WeatherGuys Editor
Because the cyclic nature of the water cycle, removal of groundwater can reduce surface water in lakes and streams. (Photo credit: The Capital Times archives)

Due to the cyclical nature of the hydrologic cycle, removal of groundwater can reduce surface water in lakes and streams. (Photo credit: The Capital Times archives)

The hydrologic cycle describes the circulation of water from the ocean and other watery surfaces to the atmosphere and to the land.

A major source of atmospheric water vapor is evaporation from the oceans. Precipitation — rain, snow, sleet or freezing rain — falls from clouds and is a loss of atmospheric water as it removes water from the atmosphere.

Precipitation returns water to the Earth’s surface and is a source of water for land. Precipitation on land may collect in lakes, run in rivers back to the ocean or percolate into the soil.

The hydrologic cycle is an interactive system. Water in the atmosphere, in the ocean, on land and underground is linked, and changing one modifies the others.

Since water plays a major role in weather and climate, it is important to understand the hydrologic cycle. A change in one component of the hydrologic cycle can affect weather. For example, a decrease in the amount of cloud cover over land during the day will allow more solar energy to reach the surface and warm the ground and the atmosphere above.

Another example is how an increased frequency in intense precipitation events over land areas can lead to flooding rather than waters seeping into aquifers.

While the hydrologic cycle is a global phenomenon, there are regional aspects that impact Wisconsin as hydrological changes across watersheds impact water supply. With ongoing climate change, shifts in precipitation patterns can impact water resources and thus management practices.

A drop in precipitation over a watershed will reduce the amount of surface waters and thus percolation into the ground. Most Wisconsin residents get their drinking water from groundwater.

Similarly, because of the cyclical nature of the water cycle, removal of groundwater can reduce surface water in lakes and streams. Groundwater recharge, water filtration and flood prevention practices may have to adapt to our observed regional climate change. Such adaptations need to consider the water cycle as an interactive system and not an isolated event.

Category: Climate, Meteorology

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