Is it possible to live on a gas giant

Predicting their planets eventual demise, they could move to floating cities. While living on these floating platforms, they could evolve further to survive independantly of the platforms; perhaps developing wings to travel between cities and lungs capable of breathing in the new atmosphere.

Living in gas dense gas : let's image the environment is a large sea of gas. Species could be a fish-like species that swimming in gas planet, or balloon like species jelly-fish, maybe at consume gas and floating around, becoming food for others gas predator. Living in gas not so dense gas : let's image the environment is a large sky with no bottom. Species could be bird-like or balloon-like.

Living on island: there are floating piece of land in gas planet where creature can live on. Those creature can look like Earth, land-based creature including tree. In Star Wars, there are creature called Purrgil , perhaps you can use as point of reference.

It was their natural ability to fly through hyperspace that inspired sentients to develop the hyperdrive technology". Purrgil is a whale that flying in space, and it feed on gas Clouzon - a kind of fuel for hyperspace on specific gas planet. They do have ability to dive into the gas planet to inhale the gas. It is good idea to check it out for the concept of "floating island" in not so dense gas planet. As an additional reference you might want to have a look at the origins of the hive in Destiny, which were living on floating islands somewhere within a gas giant.

It might also be interesting to see how they described the world and how this story developed, so I recommend looking at the books of sorrow which flesh the story out a bit. Sign up to join this community. The best answers are voted up and rise to the top. Stack Overflow for Teams — Collaborate and share knowledge with a private group. Create a free Team What is Teams? Learn more.

Life on a gas giant? Ask Question. Asked 2 years, 9 months ago. To give a sense of the pressure near the center of Jupiter, consider the Mariana Trench on Earth , the deepest place in our oceans. At nearly 7 miles 11 km deep, pressures reach just over 1, bars , kilopascals , which would feel like 8 tons of pressure per square inch , kilopascals. At sea level, you experience about 1 bar of pressure kilopascals. Near the center of Jupiter, pressures jump to megabars, or one million bars, Fletcher said.

On top of those enormous pressures, temperatures also rise into the tens of thousands of Kelvins, which is equivalent to tens of thousands of degrees Celsius. At that point, any spacecraft wouldn't be just squished or melted — it would entirely disintegrate into its constituent atoms , Fletcher said. First, the ideal gas giant probe would have to be shaped like a bullet, to improve aerodynamics and allow it to plummet as far down as possible, Fletcher said. As the spacecraft started its descent, it would encounter wispy ammonia clouds and potentially pass through blue skies, due to the same phenomenon of light scattering that occurs in Earth's atmosphere.

After passing through the "gunky, reddy brown" clouds of ammonium hydrosulfide, the spacecraft would reach about 50 miles 80 km deep, an area of "towering" cumulonimbus clouds , possibly lit up by massive lightning storms, Fletcher said. A creature that has evolved in a gaseous planet would likely be camouflaged as a lack of hiding places would make them easy prey for larger organisms.

Pressure would also be important to any creature living in the atmosphere of a gas giant. Any creature living in such an environment would need way to stay afloat, and altering its altitude would give it a distinct advantage. The idea of abundant ecosystems inhabiting planets such as Jupiter is by no means a new one. In , Carl Sagan and Edwin Salpeter published a paper in which they speculated about what such an ecosystem might look like. There is a third moon where scientists want to look for life, and this is where everything gets weird.

The Saturn moon has life-nurturing attributes undreamed of on its two icy rivals. It is the only moon in our solar system known to have a substantial atmosphere, one that is rich in complex organic molecules. In addition to water hiding under the surface, as on Europa and Enceladus, Titan also has liquid right at the surface. The moon has precipitation, storms, and seasons.

The last time NASA chose a Discovery mission, in , the project made it to the final round of three competitors, but the agency picked one more Mars explorer, the InSight lander. Europa, on the other hand, is far too big to have gotten all its water that way, so it almost surely should have existed long enough for life to take hold.

No such observations have been made on Europa. The resulting radiation poses a problem for any spacecraft in the system. Mission planners will plaster the Europa spacecraft in protective shielding, but instruments will still have to poke out, so the craft will undertake a flyby mission, rather than orbit the moon.

Its path will take big swings—45 of them—past Europa to avoid staying too long in the heat. Think how much more you can understand about an apple when you have an orange to compare it to. If Europa proves that a planet can come up with life if you give it the right chemical ingredients and leave it alone for a while, imagine what could be going on other places. Continue or Give a Gift. Daily Planet. Flight Today.