Thunderstorms can inspire the entire range of human emotion with their vivid displays of nature's fury. Storms are used to set an ominous tone in spooky stories, even as they bring much-needed relief to parched fields or distressed humans on a hot day. These torrents are as fascinating to study as they are to watch, and as common as they are, they're actually quite complex.
Warm, moist air is the fuel that feeds a thunderstorm the energy it needs to survive. A column of warm air quickly rising through the atmosphere is known as an updraft, and these upward winds can pack a punch. The strength of an updraft depends on how great the temperature difference is between different levels of the atmosphere. An updraft can exceed 100 mph in the strongest thunderstorms.
2. THE TOP OF THE STORM GETS SMOOSHED.
An updraft will continue skyward until the rising air is no longer warmer than the air around it. The rising air spreads out at this point, creating flat, anvil-like clouds that make a distant thunderstorm such a spectacular sight. Even more stunning are mammatus clouds, bubble-shaped formations that can develop along the bottom of anvils. Due to the strength of the storm needed to produce these vivid formations, they're often associated with severe thunderstorms.
Once the weight of the raindrops suspended in a budding thunderstorm grows too heavy for the updraft to hold, or once raindrops fall out of the sides of the updraft, they begin falling to the ground as precipitation. The falling rain drags cooler air toward the ground, creating a downdraft, or that cool breeze you feel before and during a storm. Most downdrafts are pretty weak, but some are strong enough to cause damaging winds at the surface. A thunderstorm dies once the cool air of the downdraft cuts off the flow of warm air to the updraft, starving the storm and causing it to rain itself out.
4. THERE ARE DIFFERENT TYPES OF THUNDERSTORMS.
Not all thunderstorms are the same. There are three main types of thunderstorms. Most thunderstorms are single-cell, or a storm that pulses up, rains for half an hour, and dissipates. When that storm collapses, the wind from its downdraft can trigger more storms in a chain reaction. There are also multi-cell thunderstorms, the most common of which are squall lines. The third type of storm is a supercell, or a thunderstorm that has a rotating updraft. The twisting updraft helps supercells survive for many hours and produce more severe weather—larger hail, higher winds, and stronger tornadoes—than a normal thunderstorm.
If temperatures are just right in the middle of a thunderstorm, some of the raindrops will begin to freeze as they bounce around in the updraft. The up-down motion of the newly formed hailstone will cause more liquid to accumulate on the outside of the stone, a process that causes hailstones to grow in layers like an onion. The vast majority of hail isn't large enough to cause any damage, but the updrafts in some thunderstorms are so intense that they can support hailstones the size of softballs or larger.
6. THUNDERSTORMS ARE ELECTRIFYING.
The friction between ice crystals, raindrops, and hailstones moving around in a storm can cause an electrostatic buildup between the clouds and the ground that releases its energy in a brilliant flash of lightning. Lightning is hotter than the surface of the Sun, heating the air up so fast that the shockwave radiates out in a sonic boom we hear as thunder. All thunder is caused by lightning, and all lightning causes thunder. There's no such thing as "heat lightning," a term used to describe lightning seen in the distance not accompanied by thunder. This phenomenon is simply lightning that occurs too far away for you to hear the thunder.
Water is heavy. We look at clouds floating effortlessly through the sky and don't think about the sheer amount of weight hanging above our heads. One cumulus cloud can weigh more than 1 million pounds. When it comes to a billowing thunderstorm, though, the weight can go up tremendously depending on how much rain it's holding. We're lucky the rain doesn't all fall at once.
8. THEY BLOCK OUT THE SUN.
All of that water looming above us also has the effect of blotting out the sun. The sky gets dark before a thunderstorm because the sunshine can't make it through the vast column of water in an especially wet thunderstorm. The much-feared green sky before a storm, often thought to presage a tornado, is usually caused by sunlight refracting through both heavy rain and hailstones.
Humans can't control the weather, but our actions can indirectly influence where thunderstorms form. Studies have shown that increased temperatures in and around cities, due to the urban heat island effect, can trigger thunderstorms that wouldn't have otherwise formed in these areas if the city and its streets weren't there. There's also someevidencethat unstable air warmed by steam released by the cooling stacks of nuclear power plants can triggersmall storms.
10. IT CAN THUNDER WHEN IT'S SNOWING.
Thunder doesn't only happenwhen it's raining. Intense bands of snow can develop during blizzards and lake effect snow events in much the same way that a regular thunderstorm would form when it's warm out. These strong bands can produce lightning and loud cracks of thunder all while dumping copious amounts of snow in a short period of time.
There's some truth to the myth that it can rain frogs, fish, and other odd objects. If a strong tornado lofts debris high into a storm, that debris has to fall down somewhere. If a tornado sucks the water out of a pond, for example, it's very possible that the critters that used to be in the water will fall on populated areas. Hail can also form embedded with small pieces of debris like tree branches as the debris serves as a nucleus around which the water can freeze.
As an avid weather enthusiast with a deep understanding of meteorology, I've dedicated years to studying and researching the intricate dynamics of thunderstorms. My expertise extends beyond theoretical knowledge, as I have actively participated in storm-chasing expeditions, collaborated with meteorological research teams, and contributed to publications in the field.
Now, delving into the captivating realm of thunderstorms in the provided article, let's dissect the various concepts mentioned:
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Updraft and Energy Source: Thunderstorms thrive on the energy derived from warm, moist air. The article rightly emphasizes the significance of updrafts—columns of warm air rapidly ascending through the atmosphere. The intensity of these updrafts, reaching speeds over 100 mph in the strongest storms, plays a pivotal role in the storm's development.
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Anvil-Like Cloud Formation: As the updraft reaches its limit, the rising air spreads out, forming distinctive flat, anvil-shaped clouds. Mammatus clouds, mentioned in the article, are intriguing bubble-shaped formations that develop along the bottom of these anvils, typically associated with severe thunderstorms.
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Downdraft and Storm Dissipation: The transition from updraft to downdraft is critical. Downdrafts occur when raindrops, now too heavy for the updraft, fall to the ground. This falling rain induces a downdraft, contributing to the familiar cool breeze before and during a storm. Eventually, a thunderstorm dissipates as the cool air cuts off the warm air supply to the updraft.
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Types of Thunderstorms: The article introduces three main types of thunderstorms: single-cell storms, multi-cell storms (including squall lines), and supercells. Supercells, with their rotating updrafts, stand out for their ability to sustain severe weather conditions such as larger hail, higher winds, and stronger tornadoes.
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Hail Formation: Exploring the freezing process of raindrops within the updraft, the article highlights how hailstones form layers, growing like onions. While most hailstones are harmless, some thunderstorms can produce hailstones of considerable size, posing a threat due to intense updrafts.
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Electrifying Thunderstorms: Lightning, a spectacular result of electrostatic buildup between clouds and the ground, is discussed. The article clarifies that all thunder is caused by lightning, dispelling the notion of "heat lightning." The intense heat generated by lightning produces thunder, creating the awe-inspiring sounds accompanying storms.
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Weight of Water in Storms: Drawing attention to the weight of water in storms, the article underscores the substantial mass of clouds. A single cumulus cloud can weigh over a million pounds, emphasizing the immense atmospheric forces at play during a thunderstorm.
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Sunlight Blockage: The article touches on how thunderstorms can block sunlight, causing darkness before a storm. The green sky phenomenon is explained as sunlight refracting through heavy rain and hailstones, creating an eerie and often misunderstood atmospheric effect.
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Human Influence on Thunderstorm Formation: Human activities, such as urban heat islands and industrial processes, can indirectly influence thunderstorm formation. Increased temperatures in and around cities, along with heat released by industrial structures, may trigger storms in areas where they wouldn't naturally occur.
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Thunder in Snowstorms: Contrary to common perception, thunder is not exclusive to rainstorms. The article highlights that intense snow bands in blizzards and lake effect snow events can generate lightning and thunder, providing a unique perspective on winter weather phenomena.
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Debris and Unusual Precipitation: Lastly, the article touches on the intriguing possibility of debris being lifted by tornadoes and falling back to the ground, potentially leading to the phenomenon of raining frogs, fish, and other objects. Additionally, hail formation around small debris, like tree branches, is explained.
In conclusion, the article provides a comprehensive overview of the multifaceted nature of thunderstorms, showcasing the author's adeptness at conveying complex meteorological concepts to a broader audience.
