There is growing evidence that raindrops are increasing in size due to climate change and rising temperatures. Several studies suggest that global warming is influencing precipitation patterns, including the size and intensity of raindrops. Here’s a summary of the key points:
This process can also cause the rain to freeze into sleet or hail, especially when the updrafts are powerful enough to push the droplets into colder atmospheric layers. As hailstones are cycled through these updrafts, they accumulate additional layers of ice, increasing in size and mass. When these larger hailstones eventually fall, they produce a significantly greater impact, contributing to the destructive potential of severe storms. This combination of larger raindrops, sleet, and hail further amplifies the intensity and damage of extreme weather events, which are becoming more common with climate change.
While more research is ongoing, there is substantial evidence that climate change is leading to larger raindrops due to increased atmospheric moisture, enhanced convection, and more intense storm systems. Moreover, the number of raindrops is also increasing. A higher concentration of raindrops in a given time and area further boosts momentum. For example, if N raindrops, each with mass m and velocity v, hit a surface area A per second, the total momentum impacting the surface is Nmv per second. This contributes to increased force and damage during rainstorms. The end result is an increase not only in the frequency and intensity of storms but also in the momentum of falling rain, which intensifies their impact.
Mass and velocity are just part of the equation; density also plays a key role. The combination of these variables increases the intensity of flow forces. Wind and water forces scale with the square of velocity, meaning that as flow speeds increase—due to more intense heating or heavier rainfall—the damage scales accordingly. According to drag physics, force is proportional to density times the square of velocity (v2v2).
* Our climate model employs chaos theory to comprehensively consider human impacts and projects a potential global average temperature increase of 9℃ above pre-industrial levels.
What Can I Do?
There are numerous actions you can take to contribute to saving the planet. Each person bears the responsibility to minimize pollution, discontinue the use of fossil fuels, reduce consumption, and foster a culture of love and care. Be a butterfly and affect the world.
The Butterfly Effect illustrates that a small change in one area can lead to significant alterations in conditions anywhere on the globe. Hence, the frequently heard statement that a butterfly in China can cause a hurricane in the Atlantic.
Here is a list of additional actions you can take.
ALSO SEE:
The Physics of Violent Rain / Brouse and Mukherjee (2024)
How is All Real Estate at Risk From Climate Change? / Brouse and Mukherjee (2024)
Flood Insurance / Brouse and Mukherjee (1995-present)
Climate Change: Atmospheric Rivers
Violent Rain and the Substrate
Climate Change, the Jet Stream, and East Coast Atmospheric Rivers
Climate Change: Rate of Acceleration
Climate Change: How Long Is "Ever"?