Factual error: Motion is physically wrong when he jumps on to the rotating scanner while floating in space above Neptune. Firstly he matches its rotation before he's even grabbed hold of it properly. Centrifugal force would rip him off it unless he's got a really tight grip on it. He even perches on the end of it, moving around in a circle, while not holding on. Violates Newton's 1st Law. (01:42:30)
Factual error: It is not possible that Pitt could have gone up to the ship when it was already blasting off. There was literally fire in the tunnel.
Suggested correction: It was a bit confusing, but what I saw was a shower of sparks or hot particles and some fumes, and no fire in the tunnel until he was through the hatch. The makers may have been influenced by seeing vapour prior to a rocket launch, and then some rockets use a shower of electric sparks to ignite the engines. It was implausible, but no fire in the tunnel.
Factual error: Pitt and the other astronauts fight at zero gravity during the take off. However, they are under acceleration, so they wouldn't be able to move.
Suggested correction: It's a bit confusing but the initial launch acceleration seems to have been short, acceleration stops, they float. Then the captain shouts to get back in their seats 'We're staging." A quick cut of a first stage booster falling away, then there's a sudden and momentary impulse, which kills the female astronaut when she hits the bottom of the chamber head first. Then there's no acceleration and they float and fight. So not obvious error.
Factual error: From the continuity of the movie it appears that the response from LIMA came within a few minutes of the transmission from Mars. This would be impossible. Even if Mars and Neptune were on the same side of the Solar System, in a straight line, they would be 4 light-hours apart, meaning the replay could not be received less than 8 hours after transmission. There's no implication that they kept Brad Pitt sitting in a room for 8 hours waiting for a reply.
Suggested correction: IIRC, there was a communication sent from earlier. It's very possible they resumed 8 hours later, even if it was the next day. And, judging by the auditors sentiment to LIMAs response (discretion), there is a chance that LIMA did not respond favorably, nor ever would have a chance hear the "emotional" version of the communication sent that day.
Suggested correction: The objective of sending McBride to Mars was for him to transmit a number of appeals to his father on a familial level. Although McBride didn't know it, his messages were intended to catch his father off-guard, making him believe his son was en route to Neptune, but actually clearing the way for a nuclear strike against the LIMA. Unfortunately, the movie fails to make it clear that the younger McBride is transmitting several sequential messages over an extended period of time before his father finally responds. This is more a matter of bad pacing and editing than it is a factual error.
It was shown that the message the father answered was exactly the one in which the son rejected the script and began to speak from the heart. And this was the same message after which the father immediately answered, while the son was still in the room.
No, Roy McBride sent more than one message, and it even shows time pass between messages. His father's reply to an earlier message only arrived coincidentally as Roy went off-script on a subsequent message.
Factual error: Regarding people walking on the moon base, the movie made no attempts at recreating the moon's gravity being 1/6 of earth's. Everyone just walks around normally like on earth. Impossible.
Suggested correction: Maybe there is some kind of artificial gravity field around the moon city, because during the moon rover chase, the gravity is apparently the normal, 1/6 Earth gravity.
There is nothing else about the technology shown in the film that would suggest such a thing is possible. All other technology shown is somewhat recognisable as an advancement on the present day. They at no point suggest the use of artificial gravity.
This correction appears to be made by someone guessing without knowledge of the film or scene. While using "maybe" in a correction could be considered valid, generally it's only when presenting a number of plausible explanations and you suggest 1 as an example. But 1 random maybe isn't acceptable, especially without in-film proof.
If the artificial gravity is developed it can be used in space travel also. But we don't see any during their space travels that they have any form of artificial gravity.
Factual error: When driving across the moon, Brad Pitt waves his hand through lunar dust that's floating in the air. But there's no atmosphere on the moon to suspend dust like that, even if was kicked up by another buggy - it would fall straight back down.
Suggested correction: Dust particles become charged by electrostatic and radiated by Ultraviolet rays from the sun. This would cause the dust particles would leap several centimeters above the surface of the moon and the lack of gravity would keep them floating there. This is why the moon has a 'Horizon Glow'. Source: https://www.sciencealert.com/nasa-just-explained-why-moon-dust-is-levitating-above-the-lunar-surface.
But these aren't "several centimetres" above the surface - they're a good metre or more up, at head height when sitting in the lunar rover.
There is no lack of gravity at that height. The particles would tend to fall back down to the surface like anything else would. They'd stay suspended at a constant altitude only if there's an upward force to balance the downward force. Even given that much, individual particles would not stay suspended stably owing to dynamics spelled out in Earnshaw's Theorem.
Factual error: A nuclear explosion couldn't kick start a rocket on its journey home as shown. There's no atmosphere, hence no shockwaves to help propel the ship forwards.
Suggested correction: The explosion itself is still a projection of energy that would push the ship. The plan itself is stupid, as it would be impossible to correctly set a trajectory, but the explosion would still push the ship.
The only way the explosion could transfer energy to the ship would be if massive pieces of the Lima slammed into the ship, destroying it.
What the spacecraft needs is some way to acquire momentum from the explosion. The explosion does convert a great deal of nuclear energy in the form of radiation, but not very much useful momentum. This was a major hurdle attacked during Project Orion back in the early 1960s, which was a program to develop an interplanetary spaceship propelled by exploding a series of nuclear bombs near to an aft pusher plate. The solution was to coat the plate's surface with a material which would ablate off the plate. The material would rise in temperature under the intensely hot radiation, with its molecular constituents vibrating violently. At a critical temperature the outermost molecules would attain escape velocity and scatter off the plate aftward. Momentum is conserved, so the aftward momentum of each escaping molecule would be balanced by an equal increase of forward momentum by the spacecraft.
The explosion creates violently expanding gases that apparently were great enough to offer some push to the rocket. Since there is no friction in space to act against the force, theoretically the ship would be pushed at the same speed as the expanding gases.
Sorry but there's no such thing in physics as 'a projection of energy that would push the ship'. Maybe you are thinking of the photoelectric effect, but this is much too small. The only thing from the explosion that would propel the rocket is mass - the Lima ship's vaporised matter which would radiate in all directions, so only a few pounds of gas would hit it - even at a huge velocity, just a little nudge.
Factual error: The Cepheus appears to be under continuous acceleration on the way to Mars, and to Neptune. That would be the only way it could travel so far so fast. So, there would not be weightlessness any any time on board the ship, unless the engines were turned off.
Suggested correction: You are making an assumption that Cepheus was under constant acceleration. It could have accelerated to the desired speed then "cruised" at that speed the rest of the way.
If Cefeus travels to Neptune in only 79 days, it should fly 500 km per second. It's a long time to accelerate to this fantastic speed, and long time to decelerate, whole time of travel easily.
Not a long time - at an acceleration of 1G (10 m/s/s) it would only take only 50,000 seconds to reach 500,000 metres/sec. That's only 13.8 hours. Also, the rocket did a slingshot manoeuvre around Jupiter and Saturn to gain speed, which fortunately (perhaps too fortuitously) must have been on the same side of the Sun as Neptune in its orbit.
Factual error: There no explanation given for why Cepheus does not have enough fuel to return to Earth. It would have been refueled on Mars and sent on a mission to Neptune. They wouldn't have sent it without enough fuel to return.
Suggested correction: It's never specifically stated, but the implication is that they are going to destroy LIMA with a nuclear weapon, and the ship and astronauts are not expected to survive.
The other astronauts knew the purpose of the travel, it's very unlikely they would have gone there to die.
Unlikely but not impossible. The suggested correction, however unlikely, is still valid.
Factual error: It is stated that at the start of the mission it is "almost full moon", the earth as seen from the moon must then be crescent, and not 3/4 full as seen on the buggydrive.
Factual error: In the movie, Neptune is shown having bright, wide rings. While the planet does have rings, in reality, they are very faint and thin. They were barely visible even from Voyager 2's flyby of the planet in 1989. They are nowhere near as big and bright as seen in the movie.