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New method would not break Einstein's Theory of Relativity

Virtually all science fiction that involves intergalactic travel or convenient travel between planets in our own solar system revolves around faster than light travel. One problem with many theories for faster than light travel is the proposed methods would violate Einstein's Theory of Relativity.

Two physicists from Baylor University have theorized what they believe to be a method of faster than light travel that would not break the Theory of Relativity. Einstein's Theory of Relativity states that objects accelerating to the speed of light require an infinite amount of energy.

The physicists -- Gerald Cleaver and Richard Obousy -- have theorized a new idea for faster than light travel that involves manipulating dark energy to propel a spacecraft. According to the universe -- in theory -- moved faster than light for a short time after the Big Bang, propelled by dark energy which represents about 74% of the mass energy budget in the universe. goes on to say that, 22% of the mass energy budget consists of dark matter and what remains of the mass-energy budget in the universe being made up of stars, planets and other things we see.

Some current evidence supports the theory that the fabric of space-time can expand faster than the speed of light. This is said to be because the reality which light travels is expanding itself.

The Baylor physicists took a recent idea in string theory to devise a method of manipulating dark energy to accelerate a spaceship based on the Alcubierre drive. The Alcubierre drive works on the principle -- in theory -- that expanding space-time behind a ship and reducing space-time in front of the ship would result in propulsion at faster than light speeds.

Cleaver said, "Think of it [faster than light travel] like a surfer riding a wave. The ship would be pushed by the spatial bubble and the bubble would be traveling faster than the speed of light."

It is believed that 10 dimensions exist, with six of them being largely unknown. M-theory suggests that hypothetical one-dimensional strings vibrate in yet another dimension. Cleaver and Obousy theorize that manipulating the dimension the strings vibrate in would alter dark energy in height, width, and length to permit a spaceship to take advantage of dark energy's effect on the universe.

Cleaver told, "The dark energy is simultaneously decreased just in front of the ship to decrease (and bring to a stop) the expansion rate of the universe in front of the ship. If the dark energy can be made negative directly in front of the ship, then space in front of the ship would locally contract."

While the whole theory hardly sounds simple, one of the greatest problems is the amount of energy required to propel a ship using this method. The physicists estimate that to move a small ship -- measuring approximately 33-feet x 33-feet -- would require energy equivalent to the entire mass of Jupiter.

Cleaver continued saying, "That is an enormous amount of energy. We are still a very long ways off before we could create something to harness that type of energy."

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RE: Theories...
By masher2 on 8/22/2008 12:15:28 PM , Rating: 4
Dark matter is never just 'ordinary matter' that we haven't yet observed. It's unobservable...with light at least; we observe it by detecting its gravitational effects.

Though in my own personal opinion, MOND (modified Newtonian Dynamics) is a more elegant explanation of the data than Dark Matter, but contemporary thought definitely strongly supports DM/DE.

RE: Theories...
By NullSubroutine on 8/22/2008 12:48:49 PM , Rating: 2
I personally think many of the troubles of the calculation of gravitational effects and acceleration is due to the fact there is no real 'zero point' in space/time. All stars, galaxies, etc are moving and there is no reference point that isn't moving.

Add that to the fact that space/time is expanding in the universe complicates matters more. I mean when everything is in motion and nothing that we know of isn't moving in a certain direction, is there really a safe point that we check mathematical hypotheses against observational data? We can easily calculate distance because of red shift, but there is no stopped point for us to accurately observe acceleration.

I looked over MOND and I wouldn't necessarily put it over Dark Matter, but I would definately put it over Luminiferous aether.

RE: Theories...
By MatthiasF on 8/22/2008 6:00:42 PM , Rating: 2
I agree somewhat albeit for a different reason.

There can never be a perfect "zero point". Everything is changing constantly, either by movement, density, energy, etc. whatever you want to call it. The only way to do precise measurements is with a reference as you suggest, and many of the references made by mankind are all abstractions based off what we encounter and is typically ruled by politics (meter, Pascal, Watt). There is really no known way to provide an absolute reference between two objects because we are part of deciding how to measure and it's typically too arbitrary to be truly helpful.

The best we can do is use multiple sources to calibrate our data. Most of our data is not calibrated well, as is the case with the red shift data that is so often used to push theories on expansion. Had we one or two move points of reference from which to calibrate (another solar system, galaxy, etc.), we could get a more accurate picture of what's going on. The more points, spaced out, at higher resolution, would yield the best results for this calibration.

Unfortunately, we can't do this yet, because we don't have interstellar ships. So, how do we learn how to travel between stars when we need to get data from other stars?

In comes the use of heavy objects in space, like Quasars, dwarfs, etc., being used as lenses. Still not all that accurate because it's being read from a single point, but at least it adds more dimension to our observations.

If we could send a signal to a lense and watch the response, we could calibrate lenses and use them to build the calibrated data we need. Only problem, it takes way too long to wait for a response (millions if not billions of years).

So, it seems we're in a conundrum. Anyone have any ideas how to get out of this rut? Could be a Noble Prize waiting for you.

RE: Theories...
By fishbits on 8/22/2008 2:36:41 PM , Rating: 3
Dark matter is never just 'ordinary matter' that we haven't yet observed.
As I said originally, when dealing with lax sources like, it is.
Astronomers Image Red Dwarf Star, One Type of Dark Matter
There are two types of dark matter, however.

Some, like the newly imaged red dwarf star, represents regular old matter wrapped up in hard-to-spot packages -- cold, dim stars that aren't readily observable with present technology...
Truly exotic dark matter, on the other hand, is thought to be made of invisible particles that have yet to be detected. ...
'Groundbreaking' Discovery: First Direct Observation of Dark Matter

If you wish to say that there aren't sources who apply the term "dark matter" to both cases, I'm afraid that's not true.

RE: Theories...
By MozeeToby on 8/22/2008 2:57:41 PM , Rating: 2
The problem is that there are two kinds of 'dark matter'.

One is matter that is literally dark, as in does not give off light and is not easily detected from earth. This would include planets, interstellar dust, black holes, and much much more.

The other kind of dark matter is believed to be different. It is mass that does not interect with other mass except through gravitation. Originally, when this kind of dark matter was first found, astronomers thought that it could be explained by normal matter that simply can't be seen. With, more evidence, it became apparent that this wasn't the case.

Now, we have one term to express two very different ideas.

RE: Theories...
By fishbits on 8/22/2008 3:22:37 PM , Rating: 2
The problem is that there are two kinds of 'dark matter'... Now, we have one term to express two very different ideas.
This wasn't stated in the post you're replying to?

RE: Theories...
By masher2 on 8/22/2008 6:07:08 PM , Rating: 2
> "Now, we have one term to express two very different ideas."

That's not a very accurate way to look at it. More precisely, we have what is called the "dark matter problem", which is the discrepancy in (among other things) gravitational effects on galaxies.

To explain that problem, a few different solutions have been proposed. One is (obviously) dark matter, more precisely known as WIMPs. -- weakly interacting massive particles. There are some other forms of dark matter, but the important point is they're all exotic -- they don't interact the way normal matter does.

As a more mundane solution to the problem, some cosmologists proposed what they called MACHOs (a play on "wimp" -- get it?). But even though MACHOs are a (proposed) solution to the dark matter problem, they aren't dark matter -- they're normal matter which just isn't illuminated.

So the "Macho" solution doesn't hypothesis dark matter, it's a solution to the problem that involves just plain old ordinary matter. There's nothing exotic at all about a MACHO. . . if the Earth was floating in space without the benefit of the sun to light it up, it would be an (albeit very small and insignificant) MACHO as well.

The problem is that the Macho solution doesn't appear to be a very good one, which leaves Dark Matter and a few other possibilities (such as MoND) to solve the problem.

RE: Theories...
By drwho9437 on 8/24/2008 12:47:31 AM , Rating: 2
My opinion is just that General Relativity is flawed. I feel like we are back in the 20s trying to do everything within the framework with more exotic explanations.

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