From the University of California – Berkeley, via Eurekalert
Jupiter, the most massive planet in our solar system, has correspondingly humongous storms, some of which last for centuries. Some of these storms also generate terrific bolts of lightning, according to a new study by University of California, Berkeley scientists. Some flashes are 100 times more powerful than lightning on Earth — and possibly much stronger.
The results come from analysis of data from NASA’s Juno spacecraft, which has been orbiting the planet since 2016 and scanning the atmosphere with its microwave radiometer, which can detect radio emissions from lightning similar to the radio interference created by lightning on Earth. Microwaves are at the high-frequency end of the radio spectrum.
Studying storms on other planets sheds light on storms on our planet, which are still not completely understood, said lead author Michael Wong, a planetary scientist at UC Berkeley’s Space Sciences Laboratory. His study was published March 20 in the journal AGU Advances.
“There’s so much we don’t know about lightning on Earth,” he said, noting that scientists over the last decade have discovered several new types of “transient luminous events” associated with thunderstorms on Earth. These TLEs — millisecond electrical phenomena in the troposphere above big storms — include sprites, jets, halos and a phenomenon dubbed ELVEs.
On Jupiter, the lightning “tells us about convection, which is how the atmosphere churns and transports heat from below,” Wong said. “Convection operates a little bit differently on Earth and Jupiter because Jupiter has a hydrogen-dominated atmosphere, so moist air is heavier and harder to bring upward.”
Air on Earth is mostly nitrogen, which is heavier than water, so added water makes moist air more buoyant. The heavier moist air on Jupiter not only means it takes a lot more energy for a storm to rise, but the storm also unleashes a lot more energy when it reaches the top of the atmosphere, leading to high wind speeds and intense, cloud-to-cloud lightning.
According to Wong, almost every spacecraft passing by Jupiter has detected lightning, mostly because the flashes stand out on the night side of the planet like a lightning bug in the dark. Based on data from previous missions, which could only detect super-powerful dark-side flashes, Jupiter got a reputation for packing more power into its flashes compared to Earth lightning. That was until a highly sensitive star-tracking camera on Juno raised doubts, detecting numerous weaker, Earth-like flashes. The problem with night-side imaging in general is that clouds can block the view of lightning flashes and make their true optical power difficult to pin down, Wong said.
Juno’s core instrument, a microwave radiometer, provided a more precise way to measure lightning’s power unaffected by obscuring clouds in Jupiter’s atmosphere. Even though the instrument was not designed to study lightning, the downward-pointing radiometer can detect microwave emissions from storms nearby.
But storms on Jupiter often occur simultaneously across belts that encircle the planet, making it hard to tell which storm produced the lightning. And without a precise location for the storm, it’s impossible to determine the power of the bolts using microwave measurements alone. Wong compared this to hearing a series of pops at a Chinese New Year’s parade and not knowing if it was exploding popcorn a few feet away or firecrackers a block away.
Stealth superstorms
Luckily, in 2021 and 2022, there was a lull in storms in the North Equatorial Belt, and Wong was able to focus on one single large storm at a time, pinpointing its location using the Hubble Space Telescope, Juno’s camera and images shared by amateur astronomers. He referred to these as “stealth” superstorms. Like true superstorms, their pattern of activity persisted for months and globally transformed the surrounding cloud structure. But unlike true superstorms, their cloud towers only reached the modest heights of small storms.
“Because we had a precise location, we were able to just say, ‘OK, we know where it is. We’re directly measuring the power,’” he said.
Juno made 12 passes over isolated storms during that period, and was close enough on four of them to measure microwave static from lightning. The flashes averaged three per second during these passes; on one flyover, Juno detected 206 separate pulses of microwave radiation. Of a total of 613 pulses measured, Wong calculated that the power ranged from about that of a lightning bolt on Earth to 100 or more times the power of an Earth bolt. Because he compared Earth lightning emissions at one radio wavelength to Jupiter lightning emissions at a different wavelength, there’s some uncertainty in the comparison, Wong cautioned. Based on one study of lightning radio emissions on Earth, Jupiter’s bolts could have been a million times more powerful than those on Earth.
Translating microwave power in a lightning bolt into total power is not straightforward, noted co-author Ivana Kolmašová, a space physicist at Charles University in Prague, Czechia, and a member of the Czech Academy of Sciences. Lightning not only emits at radio and optical wavelengths, but also generates thermal, acoustic and chemical energy. On Earth, a single bolt is estimated to release about 1 gigaJoule of total energy, or a billion Joules: enough to power 200 average homes for an hour. Wong estimates that the energy in a Jupiter bolt ranges up to 500 and perhaps as much as 10,000 times that of an Earth bolt.
The lightning is likely generated similarly to lightning on Earth, where rising water vapor condenses into liquid droplets and ice crystals that get electrically charged, leading to large voltage differences between clouds or between clouds and the ground. That’s why Earth’s thunderstorms are associated with hail. On Jupiter, while water vapor fuels the rise of storm clouds into the upper atmosphere, the charged ice crystals are made of both water and ammonia. One theory is that water and ammonia combine to form “mushballs” that fall like slushy hail.
While more powerful lightning implies higher voltages between clouds, the details of how they’re generated on Jupiter versus Earth remain a mystery, Wong said.
“This is where the details start to get exciting, where you can ask, ‘Could the key difference be hydrogen versus nitrogen atmospheres, or could it be that the storms are taller on Jupiter and so there’s greater distances involved?’” he said. Jupiter’s storms are more than 100 kilometers tall, compared to 10 kilometers on Earth.
“Or could it be that greater energy is available because with moist convection on Jupiter, you have a bigger buildup of heat needed before you can generate the storm to create lightning?” he added. “It’s an active area of research.”
Wong’s co-authors include Berkeley postdoctoral fellow Ramanakumar Sankar and colleagues from the U.S., Czechia and Japan. The research was supported by NASA (80NSSC19K1265, 80NSSC25K0362).
Journal
AGU Advances DOI 10.1029/2025AV002083
Just throwing it out there – I saw something on this site last year that mentioned / speculated that sunlight had something to do with lightning on Earth. Maybe this means other factors are more prominent, like planetary mass / composition (ferrous based stuff / iron core), or something like that?
Nah it’s CO2. 😉
The ‘Devil Gas’ !!!
Sunlight interacts with terrestrial lightning in at least two ways:
1) Sunlight drives lightning by heating the ground, creating warm, rising air currents (convection) that form charged thunderclouds which produce lightning.
2) High-speed streams of solar wind and solar radiation can interact with Earth’s magnetic field, increasing the frequency of lightning strikes by up to 30% or more during high solar activity.
I’ve never seen the role of lightning in Earth’s radiation energy balance addressed by anyone byt me in online climate discussions. Terrestrial lightning emits electromagnetic radiation over a wide range of frequencies, much (if not most) of which escapes into space. Fairly recently, NASA was surprised to find out that lightning produces gamma radiation. I mean, terrestrial lightning involves multi-million volt electric discharges, so who would have expected gamma radiation from that [hint: anyone]? Before climate scientists dismiss the role of terrestrial lightning in the climate’s energy balance as negligible, preempt them with the question of what is the average power outflow from Earth produced by terrestrial lightning? I’ve researched this deeply, and I guarantee that no one has an answer, including me. So until it is quantified, no one can say what the effect is or is not on “global warming” and climate change.
Of course you never see lightning or other latent energy effects in typical “Climate Crisis” studies — you can’t measure them with a thermometer! The thermometer-readers are so concerned with the “anomaly” of the “Global Average Temperature” that they have no time to study the real energy transport processes of the atmosphere.
“When your only tool is a thermometer…”
That’s wild https://s.w.org/images/core/emoji/17.0.2/svg/1f604.svg How do scientists even measure lightning on Jupiter from that far away? And what makes those bolts so much more powerful than the ones we get on Earth?
It is wild https://s.w.org/images/core/emoji/17.0.2/svg/1f604.svg! Scientists measure lightning on Jupiter mostly using spacecraft like Juno, which orbit the planet and carry instruments that detect radio waves and electromagnetic signals generated by lightning. These instruments can “hear” lightning from thousands of kilometers away, even though we can’t see it directly.
Jupiter’s bolts are so much stronger than Earth’s because of its massive size, deep atmosphere, and strong magnetic field. The storms there are far more intense, with more energy stored in its thick clouds of hydrogen and helium, allowing lightning to reach millions of volts—up to 1000 times more powerful than typical terrestrial lightning.
It’s basically a cosmic storm on steroids! https://s.w.org/images/core/emoji/17.0.2/svg/26a1.svghttps://s.w.org/images/core/emoji/17.0.2/svg/1f30c.svg website
If you want, I can also explain why some of Jupiter’s lightning occurs deeper in its atmosphere than on Earth—it’s pretty fascinating. Do you want me to?
Gamma rays are right next to X-rays in the electromagnetic spectrum. Despite arbitrary definitions separating the two, it appears possible there is some overlap at the source, lightning bolts. So it could be expected some low energy gammas could come from some of the more energetic bolts.
The climate was angry that day, my friends.
Like an OLD MAN, sending back soup at the deli.
The biggies in the Earth’s atmosphere are nitrogen, N2 atomic weight for the molecule, 28. Oxygen O2, 32 and water H2O, 28.
Jupiter’s atmosphere is primarily Hydrogen H2, weight 2 and Helium H, weight 2. Compared to those two, water molecules are massive.
CO2 has a weight of 44.
“H2O, 28″
Typo: must be: H2O, 18
Just the fact that they’re assuming lightning must be generated by the overturning of water vapour shows how bound up they are in earth-centric assumptions. Modelling the solar system based on how things work here is an exercise in futility, given how unique earth is compared to everything else. It would be more rational to re-assess our understanding of earth’s processes based on the behaviour of the other planets.