Post by dennisw on Aug 24, 2023 17:08:59 GMT 10
A new paper in the research journal Icarus offers dramatic proof that solar activity can affect planetary weather. The big surprise: The planet is Neptune, 2.5 billion miles from the sun. Images taken by the Hubble Space Telescope over a period of 28 years show bright clouds forming in sync with the 11-year solar cycle: The connection between Neptune and solar activity is surprising to planetary scientists because Neptune is our solar system's farthest major planet. It receives only 0.1% of the sunlight we get on Earth. Yet Neptune's cloudy weather seems to be driven by solar activity, and not the planet's four seasons, which each last approximately 40 years.
Other planets in our solar system don't behave this way. While clouds on Earth may be influenced by the solar cycle, the modulation is no more than a few percent; and even that small amount is controversial. Neptune's clouds, on the other hand, are bright, flamboyant and global. Their correlation with the solar cycle is obvious at a glance.
Chavez and her colleagues believe they have an explanation.
"Our findings support the theory that the sun's ultraviolet rays, when strong enough, may be triggering a photochemical reaction that ultimately leads to high-altitude clouds on Neptune," says Imke de Pater, emeritus professor of astronomy at UC Berkeley and a senior co-author of the study.
Their paper describes how UV rays from the sun (which are strongest when the sunspot number is high) penetrate Neptune's upper atmosphere and break apart molecules of methane gas. This sets off a chemical reaction yielding hydrocarbons (C𝑥H𝑦). If these hydrocarbons sink into the atmosphere, they could condense to form hazes and clouds.
Why doesn't this happen on every planet? "Neptune is unique," says de Pater. Unlike other planets in our solar system, Neptune has a lot of methane in its stratosphere. (How it gets there is a mystery, but that's another story.) Solar UV rays have little trouble reaching the gas and kick-starting cloud formation.
Based on the data so far, it seems to take about two years for Neptune's clouds to fully form once the solar cycle reaches its peak. Solar Cycle 25 is rising now with a peak expected in 2024. This means Neptune's cloudy season is about to begin.
More on, spaceweather.com/
Other planets in our solar system don't behave this way. While clouds on Earth may be influenced by the solar cycle, the modulation is no more than a few percent; and even that small amount is controversial. Neptune's clouds, on the other hand, are bright, flamboyant and global. Their correlation with the solar cycle is obvious at a glance.
Chavez and her colleagues believe they have an explanation.
"Our findings support the theory that the sun's ultraviolet rays, when strong enough, may be triggering a photochemical reaction that ultimately leads to high-altitude clouds on Neptune," says Imke de Pater, emeritus professor of astronomy at UC Berkeley and a senior co-author of the study.
Their paper describes how UV rays from the sun (which are strongest when the sunspot number is high) penetrate Neptune's upper atmosphere and break apart molecules of methane gas. This sets off a chemical reaction yielding hydrocarbons (C𝑥H𝑦). If these hydrocarbons sink into the atmosphere, they could condense to form hazes and clouds.
Why doesn't this happen on every planet? "Neptune is unique," says de Pater. Unlike other planets in our solar system, Neptune has a lot of methane in its stratosphere. (How it gets there is a mystery, but that's another story.) Solar UV rays have little trouble reaching the gas and kick-starting cloud formation.
Based on the data so far, it seems to take about two years for Neptune's clouds to fully form once the solar cycle reaches its peak. Solar Cycle 25 is rising now with a peak expected in 2024. This means Neptune's cloudy season is about to begin.
More on, spaceweather.com/