Speed of Light: If You're in a Spaceship, Would Results Be Skewed?

  • Thread starter Atma1001
  • Start date
In summary: This is true even if we are moving in different directions or at different speeds. So no matter how fast the Earth or any other object is moving in the universe, the speed of light will always be measured to be the same by all observers. This is a fundamental principle of relativity and has been extensively tested and proven.
  • #1
Atma1001
2
0
It's the old question of "if you're in a spaceship going near the speed of light, and you turn on your headlights..."

Think about this: Earth is spinning around the sun. The sun is spinning through the Milky Way. The Milky Way is moving away from other galaxies. That's a lot of moving around. Kinda like being in a fast-moving spaceship.

If an experiment to measure the speed of light was conducted on Earth, wouldn't the results be skewed a little because of Earth's motion? i mean, if Earth were (just go with it) going near the speed of light, and you turn on a laser (which is moving along with the earth) and fire at a target (also moving, but in relation to the laser appears stationary) in order to measure the speed of light, it seems to me that your results would be a little wacky. Space and time would be warped...right?

Now throw in the fact that Earth is moving around the sun, which is moving through a moving galaxy. Who knows how fast all the galaxies in the universe are moving, because nothing in the universe is completely stopped.

Is any of this making sense? it seems to me that in order to get a very accurate speed of light, one would have to be completely stationary. But one isn't, is one?

Any thoughts? or have i gone and confused myself again?
 
Physics news on Phys.org
  • #2
Atma1001 said:
It's the old question of "if you're in a spaceship going near the speed of light, and you turn on your headlights..."

Think about this: Earth is spinning around the sun. The sun is spinning through the Milky Way. The Milky Way is moving away from other galaxies. That's a lot of moving around. Kinda like being in a fast-moving spaceship.

If an experiment to measure the speed of light was conducted on Earth, wouldn't the results be skewed a little because of Earth's motion? i mean, if Earth were (just go with it) going near the speed of light, and you turn on a laser (which is moving along with the earth) and fire at a target (also moving, but in relation to the laser appears stationary) in order to measure the speed of light, it seems to me that your results would be a little wacky. Space and time would be warped...right?

Now throw in the fact that Earth is moving around the sun, which is moving through a moving galaxy. Who knows how fast all the galaxies in the universe are moving, because nothing in the universe is completely stopped.

Is any of this making sense? it seems to me that in order to get a very accurate speed of light, one would have to be completely stationary. But one isn't, is one?

Any thoughts? or have i gone and confused myself again?


The Michelson-Morley experiment looked for variations in the measured speed of light due to the Earth's orbital velocity, just as you describe.

It didn't find any such variation, no matter what the season, the speed of light was always found to be constant.

This led to the idea that the speed of light was constant for all observers, regardless of their state of motion - the idea of special relativity.

You might google for the MM experiment, google finds

http://galileoandeinstein.physics.virginia.edu/lectures/michelson.html

which looks like a pretty good summary. The next lecture gets into how relativity explains the null results of this experiment.
 
  • #3
Atma1001 said:
It's the old question of "if you're in a spaceship going near the speed of light, and you turn on your headlights..."

If you want more info beyond the answer above, I suggest you go to a large bookstore and check out the laymen books on special relativity. There’s a lot of good, easy ones, like Relativity Visualized, and Understanding Einstein's Theories of Relativity : Man's New Perspective on the Cosmos.
 
  • #4
If the Earth were going close the speed of light, space and time would be warped...right?

I am going to fix this sentence, in a way that is key to understanding special relativity (and resolving all your paradoxes):

If the Earth {according to person X} were going the speed of light, Space and time would be warped {according to person X}...right?

Keep in mind that person X is someone who actually see's the Earth moving near the SOL. We certaintly don't see that, from our point of view the Earth is stationary so time and space are fine.
 
  • #5
Atma1001 said:
It's the old question of "if you're in a spaceship going near the speed of light, and you turn on your headlights..."

Think about this: Earth is spinning around the sun. The sun is spinning through the Milky Way. The Milky Way is moving away from other galaxies. That's a lot of moving around. Kinda like being in a fast-moving spaceship.

If an experiment to measure the speed of light was conducted on Earth, wouldn't the results be skewed a little because of Earth's motion? i mean, if Earth were (just go with it) going near the speed of light, and you turn on a laser (which is moving along with the earth) and fire at a target (also moving, but in relation to the laser appears stationary) in order to measure the speed of light, it seems to me that your results would be a little wacky. Space and time would be warped...right?

Now throw in the fact that Earth is moving around the sun, which is moving through a moving galaxy. Who knows how fast all the galaxies in the universe are moving, because nothing in the universe is completely stopped.

Is any of this making sense? it seems to me that in order to get a very accurate speed of light, one would have to be completely stationary. But one isn't, is one?

Any thoughts? or have i gone and confused myself again?
One of the foundational postulates of relativity is that all inertial (non-accelerating) observers measure the speed of light to be the same relative to themselves. In other words, if I see a light beam zoom past me at 186,000 miles/second, then I see you zoom by in your spaceship at 100,000 miles/second, that does not mean that you will measure the light beam to be moving at 86,000 miles/second relative to yourself as would be true in Newtonian physics...instead, you will also measure it to be moving away from you at 186,000 miles/second. This has to do with the fact that velocity is measured in terms of distance/time, but different observers' clocks tick at different rates and their rulers are different lengths, and also because of the fact that different observers have different definitions of what it means for two clocks at different locations to be "synchronized".
 

What is the speed of light?

The speed of light is a fundamental constant in physics and is approximately 299,792,458 meters per second in a vacuum. It is denoted by the symbol "c".

How is the speed of light relevant to being in a spaceship?

The speed of light is relevant to being in a spaceship because it is the fastest speed at which any object or information can travel. This means that if you are in a spaceship traveling at a speed close to the speed of light, the laws of physics will behave differently than they do on Earth.

What is time dilation and how does it relate to the speed of light?

Time dilation is a phenomenon where time appears to slow down for an object or person moving at high speeds. This is a consequence of Einstein's theory of relativity, which states that the laws of physics are the same for all observers moving at a constant speed. As you approach the speed of light, time dilation becomes more pronounced, with time appearing to slow down significantly.

Would the results of experiments conducted in a spaceship traveling at the speed of light be skewed?

Yes, the results of experiments conducted in a spaceship traveling at the speed of light would be skewed. This is because the speed of light is the maximum speed at which any object or information can travel, so the laws of physics would behave differently at this speed. Time dilation, length contraction, and other relativistic effects would all impact the results of experiments.

Is it possible for a spaceship to travel at the speed of light?

No, it is not possible for a spaceship to travel at the speed of light. According to Einstein's theory of relativity, an object with mass cannot reach the speed of light because it would require an infinite amount of energy. However, scientists are exploring ways to approach the speed of light, such as using powerful propulsion systems and harnessing the energy of black holes.

Similar threads

B What if You Were Completely Still in Space? Exploring the Effects of Motion
    • Special and General Relativity
Replies
25
Views
2K
I Effects of time dilation for near-speed-of-light travel
    • Special and General Relativity
2
Replies
65
Views
4K
B A Scenic Trip as a Spaceship at 0.999...c, and questions that arise
    • Special and General Relativity
2
Replies
36
Views
2K
I Is the concept of a one-way speed of light meaningful and measurable?
    • Special and General Relativity
Replies
25
Views
2K
I What was the role of frequency in the Michelson-Morley experiment's null result?
    • Special and General Relativity
Replies
3
Views
430
I Time dilation for the Earth's orbit around the Sun
    • Special and General Relativity
2
Replies
58
Views
5K
B New Paradox Discovered, I Think
    • Special and General Relativity
3
Replies
98
Views
2K
I Twin paradox for (accelerated) dummies?
    • Special and General Relativity
2
Replies
36
Views
3K
B Thought Experiment : Try and get Alice to "0%" the Speed of light
    • Special and General Relativity
Replies
15
Views
1K
B Energy, Mass, Speed of Light: Can We Reach It?
    • Special and General Relativity
Replies
9
Views
1K

Hot Threads

Recent Insights

Back
Top