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As we all know Jupiter is a gaseous gas giant and it has a large mass, almost twice the sum of all other planets in the Solar system. So, if it happens that we go to Jupiter and as we know it does not have a hard surface, we could not stand on it. So what would happen if we dived into it? Would we will float on the surface (I don't think so), or would we be crushed into pieces due to gravity pull dragging us to the center of the planet with its whole mass above us?

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(*) Jupiter, for all intents and purposes, doesn't have a solid surface to stand on. Not any more than you could say that Earth's atmosphere has it, before you hit Terra Firma. It's an enormous ball composed of mostly Hydrogen and Helium, but also other heavier elements in smaller parts, and it's so massive that its own gravity compresses these gases into liquid the further into its interior we go. Lighter elements dominate in its upper atmosphere in gas state; these gradually compress due to its own pressure into liquids, deeper still metallic Hydrogen, and eventually mesh of metallic Hydrogen, rock, and other heavier elements that sunk deeper into its core. Nobody would be able to "stand" on any of these layers. In fact the temperature and pressure become so great, it's been calculated that even diamonds (it's speculated they could form as precipitates in certain layers of Jupiter's interior from black clouds of soot, where, if proven true, would mean it quite literally "rains diamonds") eventually melt into, again speculated, gooey form of liquid carbon that's not so much unlike tar, except that it isn't.

                                   Jupiter vertical section

                                          A pie slice of Jupiter's pressure, temperature and density layers. Source:
                                Laboratory for Atmospheric and Space Physics, University of Colorado at Boulder

So what would happen if you dived into Jupiter? Well, how long you'd last would depend on what gear you're in that protects you from its hostile environment. Pressure would at first gradually increase in its upper atmosphere to the point that it's sufficient for its violent storms to throw you around. That's the Jupiter's cloud layer. You might be "lucky" though, and fall into it at its poles where giant atmospheric depressions keep all of it somewhat lower, slightly prolonging the inevitable outcome. As the pressure increases, so does thermal convection. You'd start losing heat increasingly more rapidly, and it's not a nice Mediterranean spring temperature either. At one atmosphere (pressure equal to mean sea-level on Earth) the temperature goes as low as −108 °C. That's below the coldest temperatures ever recorded on Earth's surface (~ −93 °C in the East Antarctic Plateau), even for its polar regions during winters. All the while, you'd also be bombarded by Jupiter's radiation. And if you're falling into it from its poles and you thought you were lucky for a few hundred kilometers more, think again because those are the regions where Jupiter magnetically reconnects with Sun's own magnetic field, increasing speed of charged particles to the point that we can observe fantastic "electric blue" polar aurorae the size of many Earths where this Solar proton flux ionizes Jupiter's upper atmosphere.

So you have three main adversaries to fight against with your environmental protective gear you're in: radiation, pressure, and temperature. And if you enter its upper atmosphere too fast, also contact ionisation, triboelectric charge, surface ablation… nothing too charming and all of it quite terminating on its own. When would any of these be too much to stand and your equipment fails is anyone's guess, but it wouldn't take very long at Jupiter's gravity (24.79 m/s²), regardless of your initial descent rate, until you dive too deep for comfort.

Eventually, once long dead from gas giant inhospitability, your remains would submerge deeper into Jupiter's liquid Hydrogen layer. First freeze solid, then thaw as the temperature and pressure increase to nearly 5,000 °C and about 2 million times Earth's sea-level atmospheric pressure. You'd nearly implode, if your body wasn't mostly water, which doesn't compress easily. You would still compress greatly as all your body's once functioning cavities collapse. Not the best time for a selfie. Your journey isn't yet over though, because you and your gear you're in are still denser than that particular Jovian layer and would sink deeper still towards its metallic Hydrogen layer that starts at a density of roughly 1 g/cm3 and continues to nearly 25 g/cm3 (with average density of ~ 4 g/cm3, or slightly more than 4 times your own body's density, if we excluded an EVA suit you'd have to be in, adding to your overall density. At that point, you're being zapped by tremendous electric currents that give Jupiter such an enormous magnetosphere, the second largest structure in our Solar system besides the Sun's own heliosphere.

These currents would tear your remains apart into indistinguishably small fragments, and induce chemical decomposition by free atomic Hydrogen radicals randomly exchanging electrons. It would look a bit like submerging a body into hydrofluoric acid while deep frying it at the same time, if perhaps not more violent. I don't know, I can only imagine, I've never actually done it. Honest! Anyway, fragments of what was once you would decompose into its constituent chemical elements, lose valence and bound with surrounding free hydrogen protons. Heavier compounds would sink even deeper, where the pressure and current would eventually cause them to lose hydrogen protons and recombine with themselves or other heavier elements and electron hungry molecules present into so compressed and hot state not even current science is able to tell their exact nature and behavior.

Either case, you'd be spread all over Jupiter's interior in various states, and become a part of it for near to eternity. Pretty epic, but please don't do it.


(*) Not all of it might be necessarily exactly true, since some parts I describe are a subject to still ongoing research, but this was kinda fun so I went for it. I'll revise to add some references at a later time for the parts that there are any available.

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  • $\begingroup$ Reading this I assumed that metallic hydrogen would be a solid. But apparently it could be either a liquid or a solid under these conditions. $\endgroup$ – Hobbes Sep 29 '15 at 17:08
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    $\begingroup$ @Hobbes Solid metallic hydrogen wouldn't explain Jupiter's enormous magnetosphere. Direct evidence is still elusive, but indirect ones are quite solid (pardon the pun LOL). If it interests you more, one good lecture I watched that is still fairly recent is Siegfried Glenzer's (SLAC) Jupiter in a Bottle: Extreme States of Matter in the Laboratory (more info here). $\endgroup$ – TildalWave Oct 18 '15 at 16:02
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    $\begingroup$ @tidalwave Nice answer for as far as it goes, but one thing I think the person was getting at the assumed crushing power of gravity at the center, which was not answered. The writer spoke of the center "with its whole mass above us". Forgetting for a moment the impossibility of it being a human adventure, the gravity at the center would be zero because the amount of mass in all directions is the same. The issue of gravity at the center of large mass (earth) was answered somewhere in earth science, stackexchange last year $\endgroup$ – user13927 Mar 31 '16 at 1:02
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    $\begingroup$ Fun and educational... I mean, not to dive in Jupiter's atmosphere. $\endgroup$ – fro_oo Jun 8 '16 at 10:25
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    $\begingroup$ This reads like an xkcd what-if! $\endgroup$ – Brian Feb 16 '17 at 17:58
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If we ignore the atmospheric effects for a moment, let's see what gravity does as you descend into a planet (and this goes for all planets, rocky or gaseous).

According to Newton's Shell theorem, inside a sphere of uniform density, gravity is proportional to your distance to the center. Gravity is highest when you're on the surface, with all of the planet's mass below you. When you're at the center of the planet, gravity is 0 because the pull from different directions cancels each other out.

Jupiter isn't uniform, so the equation becomes more complicated.

You get F = gM/r2, where g is the gravitational constant. M is the mass of the sphere with radius r, this depends on the average density of the sphere.

For Earth, the gravity profile looks like this:

Earth gravity profile. Gravity stays more or less constant from the surface down to 0.5 times the planet radius. From there to the center of the planet, gravity drops linearly to 0.

For Jupiter you get a profile that's more pronounced because the difference in density between the outer layers and the core is more extreme.

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  • $\begingroup$ Surely that drawing can't be to scale? It looks like the difference from the center of Earth to the boundary between the outer and inner core (about 1200 km) is on the same order of magnitude as the difference between ground level and the space shuttle typical orbit at 400 km. $\endgroup$ – a CVn Mar 31 '16 at 8:31
  • $\begingroup$ I replaced the drawing with a more accurate graphic. $\endgroup$ – Hobbes Mar 31 '16 at 9:16
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This article enclosed with video: What If You Fell Into Jupiter depicts what would happen if we dive/fell into Jupiter.

The interesting video source is from What.If show created by Hashem Al-Ghaili on Facebook. It's not that technical to understand yet very informative. I hope you like it, Hashem is my favorite science page (public figure as well) on FB, along with many more of its subsidiary scientific channels.

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protected by a CVn Feb 15 '17 at 20:39

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