Faster-Than-Light Travel/Analysis

In real space, even approaching lightspeed would require more energy per second than all of Earth's industries use per year. While this may be explained by advances in technology, the general formulas for velocity and acceleration are such that as you approach the speed of light, the energy needed to accelerate anything with non-zero mass increases asymptotically. In other words, you need an infinite amount of energy (and an infinite amount of time) to accelerate to the speed of light.

Additionally, Albert Einstein's well-supported Special Relativity theory holds that FTL travel simply cannot work, by the fundamental laws of physics. Due to the space-time distortion at relativistic speeds, it would imply violations of causality itself! For example, a superluminal signal sent from A to B will appear, in another reference frame, to be received before being sent. This is the reason why some say that FTL travel implies time travel -- but that is sloppy language. What actually happens is that causality is thrown out of whack, and that different observers don't always agree whether effects precede their causes or not. In effect, this means that, in special relativity, going faster than light is impossible -- with or without time travel. In Einstein's much more comprehensive theory of General Relativity, however, matters are considerably more complex, and FTL travel is not known to necessarily imply causality violations (see Real Life examples below)... But, all in all, suffice it to say that having the protagonists' rocketship outrun a beam of light will always require some serious hand waving by the author. See also Time Dilation.

Even outside of Einstein's flavor of Relativity, other theories tend to impose limitations just as strict. Note that once the gravity is not the same as spatial anomalies, it's likely to be affected by them -- which may be bad news for massive objects close to even-more-massive objects.