Expert Voices

In the new Disney Pixar movie Lightyear, time gets bendy. Is time travel real, or just science fiction?

Buzz Lightyear and his new crew in Disney's new "Lightyear" film.
Buzz Lightyear enters the time/space continuum in a "Toy Story" spinoff. (Image credit: Disney/Pixar)

This article was originally published at The Conversation. The publication contributed the article to's Expert Voices: Op-Ed & Insights.

Sam Baron, Associate professor, Australian Catholic University

At the beginning of the new Disney Pixar film, "Lightyear," Buzz Lightyear gets stranded on a dangerous faraway planet with his commanding officer and crew.

Their only hope of getting off the planet is to test a special fuel. To do that, Buzz has to fly into space and repeatedly try to jump to hyper-speed. But each attempt he makes comes with a terrible cost.

Every time Buzz takes off for a four-minute test flight into space, he lands back on the planet to find many years have passed. The people Buzz cares most about fall in love, have kids and even grandkids. Time becomes his biggest enemy.

What's going on? Is this just science fiction, or could what happened to Buzz actually happen?

Related: NASA channeled its inner Buzz Lightyear with this wild Z-1 spacesuit concept

Time is relative: Einstein's big idea

Buzz is experiencing a real phenomenon known as time dilation. Time dilation is a prediction of one of the most famous scientific theories ever developed: Albert Einstein's theory of relativity.

Prior to relativity, the best theory of motion we had was Isaac Newton's mechanics.

Newton's theory was incredibly powerful, providing stunning predictions of the motion of the planets in our solar system.

In Newton's theory, time is like a single giant clock that ticks away the seconds in the same way for everyone. No matter where you are in the universe, the master clock will display the same time.

Read moreCurious Kids: is time travel possible for humans?

Einstein's theory of relativity shattered the master clock into many clocks — one for each person and object in motion. In Einstein's picture of the universe, everyone carries their own clock with them.

One consequence of this is there is no guarantee the clocks will tick at the same rate. In fact, many clocks will tick at different rates.

Even worse, the faster you travel relative to someone else, the slower your clock will tick compared to theirs.

This means if you travel very fast in a spaceship — as Buzz does — a few minutes might pass for you, but years might pass for someone on the planet you left behind.

Time traveling forward — but not backward

How time dilation works: minutes for one person can be years for another. (Image credit: Disney/Pixar)

In a sense, time dilation can be thought of as a kind of time travel. It provides a way to jump into someone else's future.

This is what Buzz does: he jumps into the future of his friends left on the planet below.

Unfortunately, there is no way to use time dilation to travel backwards in time, into the past (as one important character talks about later in the film).

It's also not possible to use time dilation to travel into your own future.

That means there's no known way for you to travel into the future and meet your older self, simply by going really fast.

Time travelers above Earth right now

Time dilation might seem like science fiction, but in fact it is a measurable phenomenon. Indeed, scientists have conducted a number of experiments to confirm that clocks tick at different rates, depending on how they are moving.

For example, astronauts on the International Space Station are traveling at very high speeds compared with their friends and family on Earth. (You can watch the space station pass overhead if you know when to look up.)

This means those astronauts are aging at a slightly slower rate. Indeed, US astronaut Buzz Aldrin, from whom Buzz in Lightyear gets his name, would have experienced a tiny bit of time dilation during his trip to the moon in the 1960s.

Real-life astronaut Buzz Aldrin would have experienced a tiny bit of time dilation on his trip to the Moon in 1969. (Image credit: NASA)

Don’t worry, though, the astronauts on the International Space Station won’t feel or notice any time dilation. It's nothing like the extreme time jumps seen in Lightyear.

Aldrin was able to return safely to his family, and the astronauts up in space now will too.

To infinity — and beyond

Clearly, time dilation could have a serious cost. But it's not all bad news. Time dilation could one day help us travel to the stars.

The universe is a massive place. The nearest star is 40,208,000,000,000 km away. Getting there is like traveling around the world one billion times. Traveling at an ordinary speed, no one would ever survive long enough to make the trip.

Time dilation, however, is also accompanied by another phenomenon: length contraction. When one travels very fast toward an object, the distance between your spaceship and that object will appear to be contracted.

Very roughly, at high speeds, everything is closer together. This means that for someone traveling at a high speed, they could make it to the nearest star in a matter of days.

But time dilation would still be in effect. Your clock would slow relative to the clock of someone on Earth. So, you could make a round trip to the nearest star in a few days, but by the time you arrived home, everyone you know would be gone.

That is both the promise, and the tragedy, of interstellar travel.

This article is republished from The Conversation under a Creative Commons license. Read the original article.

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Sam Baron
Associate professor, Australian Catholic University

Dr Baron's present research focuses on the connection between key topics in the philosophy of mathematics concerning mathematical ontology, and topics in the philosophy of time concerning temporal ontology. A central focus of this research is the role of truthmaking and non-causal explanation in arguments both for and against particular ontological views.

Dr Baron is currently investigating the role of non-causal explanation in the indispensability argument for the existence of mathematical objects, as well as timelessness in theories of quantum gravity and timelessness in metaphysics more generally.