How Would 10x Gravity Affect You?

So what you’re saying is, that I... CAN GET STRONGER!

deadphones

Love the new background.

So basically... Goku is f**king too strong since he did 100x Gravity later on.

dragonknight

That means the 40 tons Goku couldn't lift weren't 40 tons since he was on King kai's planet, making what SCREWATTACK said even more bs

All I can say is I knew it

MrTreymeister

In 10 times gravity you would be crapping out your own spine.

wrath

I think the obvious answer is we would die, 1 G puts the body through enormus ammounts of stress. Let alone imagine what 10 G's would do

ajarofpickles

2:07 OH LOOK!... Goku did Naruto's ninja run before Naruto was even a thing. I mean granted, I saw DBZ before Naruto but I had forgotten the way Goku chased after bubbles right here!;)

raysullivan

THEN HOW YAMCHA SURVIVE MORE THAN 10 GS

onehitwonders

About those drawbacks I got two words for you

Ki control

bryantcoleman

You should do another Q&A since you've surpassed the 40k mark on your main channel. Also congrats on 42k subs JAR, keep it up.

brewdog

Please excuse me for chiming in but submerging yourself in water does not reduce the physical stress because of g forces due to low compressibility. The compressibility factor only comes into play when the forces change direction or intensity. In this case, the low compressibility of water causes it to remain at the same density both at the parts of the fluid that are now in the direction of the force and those that are now in the opposite direction. However, this is only half of the effect and the other half is the important part when discussing static forces as they would occur in your 10x gravity scenario. This other half is the actual density of water. Water has a density of 997 kg/m³, give or take based on temperature and dissolved minerals. This density is strikingly close to the average human density of 985 kg/m³. This means that the buoyancy, the force pushing in the opposite direction of the static force on the object in the liquid, is almost identical to the gravitational force. This means that two forces are applied to the object (here, the human) which are roughly equal in intensity and of opposite direction (described by anti-parallel vectors). In other words, they basically cancel each other out (but not completely which is a hard limit on the type of suit you mentioned). The almost-identical densities also are why humans can swim and dive in water. Back to the scenario in which forces change direction and/or intensity, the low compressibility is very important because otherwise the fluid would change density and pressure without the fluid at the opposite end having the same density and pressure immediately. The equal distribution mentioned in the wikipedia page excerpt you put on screen is an overcomplicated way of saying the same. Due to the density being equal the forces applied by the liquid on the body is equal in the direction of the applied force and opposite of it because the water itself tries to go in that direction as well.

Please note that the excerpt is absolutely right but might use a term confusing to those who read it. The excerpt states that fluids distribute applied forces equally as omnidirectional pressure. Fluids, however, are not just water and not just liquid substances. Air is also a fluid and the same principle applies for this mixture of gases. The important differences are the low compressibility which makes sure that under sudden changes the system reaches that omnidirectional pressure fast and the density which makes sure that the fluid does not "want" any more or less to be accelerated in the direction of the applied force. Since the first point does not apply for a static scenario like being submerged in water on a planet with 10g, arguing based on compressibility is plainly wrong. It should have been an argument based on density.

Then again, I could be wrong so please tell me if you notice anything off in this explanation.

-Coppergears

P.S. Not only superhuman strength is needed but also superhuman stress resistance. Just being strong enough to support yourself won't do any good if the bones break under the excessive stress applied by gravity or even your own muscles. Have a look at this report, especially page 5 in the upper left corner where you will find a report of D8 and D9 vertebrae (which reside somewhere around the middle of the spine) being fractured during flight in a MiG 21 aircraft:

Coppergears

Lower than 1 G causes muscle decay. Would say, 1.5 or 2g be good for you?

DarkWarchieff

Just A Robot can you make a top ten favorite cartoon characters list. A list of Cartoon Characters that you just Absolutely love watching. and also Thank You for making such entertaining videos, They'er really fun and informative to watch.

wallywest

Can humans gradually get accustomed to increase of gravity? Like for example raising the gravity 1x every time the body adjusts to it and gets more durable.

DottaNatural

Theirs a anime called Outlaw Star where the main character has to go on a heavy gravity world to break someone out of prison.

Nikoli

my question is how would people be affected by 2 times gravity?....like could you actually survive and eventually get use to it?...

Draconicus

i love the new background. much better than the generic modern house

wesleyvanpelt

The only feasible way gravity training would work is if you could change to gravity by 1/100ths or less (by less I mean 1/1000ths, 1/10000ths etc) aswell as giving your body ALOT of time to adjust (over a month for each 1/100th) this would still be extremely dangerous.

zeragnon

Why would gravity effect time and also would the higher gravity stop you from blinking or even burst your ear drums?

hordebucket

Will you make a video about TMossBoss's video: just a robot is not creative?

mfdoom

Sup man if you're reading this I have a question will you ever have a discussion about Goku versus Pegasus Seiya topic?

jeremybriggs