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As a practical goal interstellar travel has been debated fiercely by various scientists, science fiction authors, hobbyists and enthusiasts.
Many scientific papers have been published about related concepts. Given sufficient travel time and engineering work, unmanned interstellar travel is certainly possible. NASA has been engaging in research into these topics for several years, and has accumulated a number of theoretical approaches.
Interstellar travel poses a number of difficulties. There are all the difficulties of interplanetary travel, including hard vacuum, radiation, micrometeoroids, and free fall. These difficulties seem tractable; robot missions have been sent to almost every planet in the Solar system, humans have been sent to the Moon, and manned missions to Mars have been planned for years. Interstellar travel is made immesurably more difficult by the tremendous distance to even the nearest stars.
Astronomical distances are sometimes measured in the amount of time it would take a beam of light to travel. Light in a vacuum travels in approximately 3×108 metres per second, which is denoted with the letter c, so a light second is approximately 3×108 metres.
The distance between Earth and its Moon is about one and a quarter light seconds. With current propulsion technologies, such a trip will typically take about three days for a spacecraft.
The distance from Earth to other planets in the solar system ranges from three light minutes to about five and a half light hours. Depending on the planet and its alignment to earth, for a typical unmanned spacecraft these trips will take from a few months to a little over a decade.
The nearest star to the Sun is the triple system Alpha CentauriAlternative meaning: Alpha Centauri computer game Alpha Centauri is the brightest star system in the southern constellation of Centaurus, and is the third brightest in the entire night sky (although too far south to be visible in most of the northern hemi. Light radiating from that star takes a bit more than four years to reach Earth. Currently, the fastest spacecraft built can achieve a velocity of about 30 km per second (relative to Earth). At that rate, the journey would take about 40,000 years. Additionally, at current stage of space technology, the longest space missions that have been initiated are expected to have an operational lifetime of about forty years before failure of key components is likely to happen. Significant engineering advances such as automated self-repair may be required to ensure survival.
In short, current spacecraft propulsionStennis Space Center in Hancock County, Mississippi Spacecraft propulsion is used to change the velocity of spacecraft and artificial satellites, or in short, to provide delta-v. There are many different methods. Each method has drawbacks and advantages, technology cannot send objects fast enough to reach the stars in a reasonable time.
Even theoretical interstellar travel is expected to be slow. Current theories of physics predict that it will be impossible or very difficult to travel faster than light, and that if it were possible, it would also be possible to build a time machine. This possibility seems unlikely, although Robert L. Forward has written a novelA novel is a long or extended work of fiction written in prose, usually in the form of a story. It is longer and more complex than a short story or novella (ie. 40,000+ words), and it is not bound by the restrictions of plays and poetry. The word "novel", Timemaster , which describes how this could be done, assuming that one could find negative matter.
However, special relativitySpecial relativity (SR or the special theory of relativity is the physical theory published in 1905 by Albert Einstein. It replaced Newtonian notions of space and time, and incorporated electromagnetism as represented by Maxwell's equations. The theory is and general relativity offer the possibility of shortening the apparent travel time: with sufficiently advanced engines, a starship could make interstellar voyages at nearly the speed of light, and relativistic time dilation would make the voyage seem much shorter. However, upon arrival, the passengers would discover that the full time had passed in the world outside the starship.
Even this possibility still leads to very long travel times without the use of exotic physics. For a lengthy voyage, the spacecraft cannot accelerate at much more than one Earth gravity, since its acceleration will provide artificial gravity for the passengers, and the passengers cannot long tolerate high gravity. This means that if the ship accelerates throughout the voyage, accelerating on the way out and decelerating on the way back, in a year of ship time, the ship can travel half a light year. Because the ship can accelerate for longer, in two years the ship can go four times as far, or two light years. In three years, the ship could reach Alpha Centauri. More than five years will have passed on Earth. This is a long voyage, but still not much worse than ancient sailing voyages.