Can you tie a knot in four dimensions? A mathematician explains

1. Physics & Mathematics

Can you tie a knot in four dimensions? A mathematician explains

News By Zsuzsanna Dancso published 5 March 2026

An academic dives into the physics of multiple dimensions and whether it's possible to tie a knot in 4D.

When you purchase through links on our site, we may earn an affiliate commission. Here’s how it works.

Could knots be tied in the 4th dimension? Physicists think probably not. (Image credit: Andriy Onufriyenko via Getty Images)

• Copy link
• Facebook
• X
• Whatsapp
• Reddit
• Pinterest
• Flipboard
• Email

Share this article 0 Join the conversation Follow us Add us as a preferred source on Google Newsletter Live Science Get the Live Science Newsletter

Get the world’s most fascinating discoveries delivered straight to your inbox.

Become a Member in Seconds

Unlock instant access to exclusive member features.

Contact me with news and offers from other Future brands Receive email from us on behalf of our trusted partners or sponsors By submitting your information you agree to the Terms & Conditions and Privacy Policy and are aged 16 or over.

You are now subscribed

Your newsletter sign-up was successful

Want to add more newsletters?

Delivered Daily

Daily Newsletter

Sign up for the latest discoveries, groundbreaking research and fascinating breakthroughs that impact you and the wider world direct to your inbox.

Signup +

Once a week

Life's Little Mysteries

Feed your curiosity with an exclusive mystery every week, solved with science and delivered direct to your inbox before it's seen anywhere else.

Signup +

Once a week

How It Works

Sign up to our free science & technology newsletter for your weekly fix of fascinating articles, quick quizzes, amazing images, and more

Signup +

Delivered daily

Space.com Newsletter

Breaking space news, the latest updates on rocket launches, skywatching events and more!

Signup +

Once a month

Watch This Space

Sign up to our monthly entertainment newsletter to keep up with all our coverage of the latest sci-fi and space movies, tv shows, games and books.

Signup +

Once a week

Night Sky This Week

Discover this week's must-see night sky events, moon phases, and stunning astrophotos. Sign up for our skywatching newsletter and explore the universe with us!

Signup +

Join the club

Get full access to premium articles, exclusive features and a growing list of member rewards.

Explore An account already exists for this email address, please log in. Subscribe to our newsletter

We all know we live in three-dimensional space. But what does it mean when people talk about four dimensions?

Is it just a bigger kind of space? Is it "space-time," the popular idea which emerged from Einstein's theory of relativity?

If you have wondered what four dimensions really look like, you may have come across drawings of a "four-dimensional cube". But our brains are wired to interpret drawings on flat paper as two- or at most three-dimensional, not four-dimensional.

You may like

• 'Collective hum' of black holes could settle the debate over new physics
• Our model of the universe is deeply flawed — unless space is actually a 'sticky' fluid
• Scientists taught robots to swim through mazes using Einstein's relativity

The almost insurmountable difficulty of visualising the fourth dimension has inspired mathematicians, physicists, writers and even some artists for centuries. But even if we can't quite imagine it, we can understand it.

What is dimension?

The dimension of a space captures the number of independent directions in it.

A line is one-dimensional. We can move along it forwards and backwards, but these are opposite, not independent, directions. You can also think of a string or piece of rope as practically one-dimensional, as the thickness is negligible compared with the length.

You can move forwards along a rope, or backwards – but not side to side. (Image credit:  Zsuzsanna Dancso, CC BY)

A surface, such as a soccer field or the skin of a balloon, is two-dimensional. There are independent directions forwards and sideways.

Sign up for the Live Science daily newsletter now

Get the world’s most fascinating discoveries delivered straight to your inbox.

Contact me with news and offers from other Future brandsReceive email from us on behalf of our trusted partners or sponsorsBy submitting your information you agree to the Terms & Conditions and Privacy Policy and are aged 16 or over.

You can move diagonally on a surface, but this is not an independent direction because you can get to the same place by moving forwards, then sideways. The space we live in is three-dimensional: in addition to moving forwards and sideways, we can also jump up and down.

Four-dimensional space has yet another independent direction. This is why space-time is considered four-dimensional: you have the three dimensions of space, but moving forward or backward in time counts as a new direction.

One way to imagine four-dimensional space is as an immersive three-dimensional movie, where each "frame" is three-dimensional and you can also fast-forward and rewind in time.

What to read next

• How many holes does the human body have?
• Our leading theory of dark matter may be wrong, huge new gravity study hints
• 'Proof by intimidation': AI is confidently solving 'impossible' math problems. But can it convince the world's top mathematicians?

Consider the cube

A powerful tool for understanding higher dimensions is through analogies in lower dimensions. An example of this technique is drawing cubes in more dimensions.

A "two-dimensional cube" is just a square. To draw a three-dimensional cube, we draw two squares, then connect them corner to corner to make a cube.

So, to draw a four-dimensional cube, start by drawing two three-dimensional cubes, then connect them corner to corner. You can even continue doing this to draw cubes in five or more dimensions. (You will need a large piece of paper and need to keep your lines neat!)

A two-dimensional, a three-dimensional and a four-dimensional cube. (Image credit:  Zsuzsanna Dancso, CC BY)

This experiment can help accurately determine how many corners and edges a higher-dimensional cube has. But for most of us, it will not help us "see" one. Our brains will only interpret the images as complex webs of lines in two or at most three dimensions.

Knots

We can tie knots in three dimensions because one-dimensional ropes "catch on each other". This is why a long rope wound around itself, if done right, won't come apart. We trust knots with our lives when we're sailing or climbing.

Two ropes catch on each other if pulled in opposite directions. This is what makes knotting possible. (Image credit: Zsuzsanna Dancso, CC BY)

But in four dimensions, knots would instantly come apart. We can understand why by using an example in fewer dimensions, like we did with cubes.

Imagine a colony of two-dimensional ants living on a flat surface divided by a line. The ants can't cross the line: it's an impassable barrier for them, and they don't even know the other side of the line exists.

A colony of flat ants in a two-dimensional world don’t even know that a world on the other side of the line exists. (Image credit: Zsuzsanna Dancso, CC BY)

But if one day an ant, and its world, becomes three-dimensional, that ant will step over the line with ease. To step over, it needs to move just a tiny bit in the new, vertical direction.

If one ant becomes three-dimensional, it can see across the line and step over it with ease. (Image credit: Zsuzsanna Dancso, CC BY)

Now, instead of an ant and a line on a flat surface, imagine a horizontal and a vertical piece of rope in three dimensions. These will catch on each other if pulled in opposite directions.

But if the space became four-dimensional, it would be enough for the horizontal piece of rope to move just a little bit in the new, fourth direction, to avoid the other entirely.

Thinking of four dimensions as a movie, the pieces of rope live in a single, three-dimensional frame. If the horizontal piece of rope shifts just slightly into a future frame, in that frame there is no vertical piece, so it can easily move to the other side of the vertical piece before shifting back.

Imagine four-dimensional space as a movie of three-dimensional frames. The bottom left cube shows a horizontal piece of rope in front of a vertical piece, both in the ‘present’ frame. The horizontal piece can move into the future frame (second column), where it is able to slide towards the back (third column), then move back into the present frame, now behind the vertical piece.  (Image credit: Zsuzsanna Dancso, CC BY)

From our three-dimensional perspective, the ropes would appear to slide through each other like ghosts.

Knots in more dimensions

Is it impossible, then, to knot a rope in higher dimensions? Yes: any knot tied on a rope will come apart.

But not all is lost: in four-dimensional space you can knot two-dimensional surfaces, such as balloons, large picnic blankets or long tubes.

There is a mathematical formula that determines when knots can stay knotted: take the dimension of the object you want to knot, double it, and add one. According to the formula, this is the maximum dimension of a space where knotting is possible.

The formula implies, for example, that a rope (one-dimensional) can be knotted in at most three dimensions. A (two-dimensional) balloon surface can be knotted in at most five dimensions.

Studying knotted surfaces in four-dimensional space is a vibrant topic of research, which provides mathematical insight into the the still poorly understood mysteries into the intricacies of four-dimensional space.

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

Zsuzsanna DancsoAssociate Professor of Mathematics, University of Sydney

Zsuzsanna Dancso is a mathematician working in quantum topology. She studies knots in three and four dimensional spaces, and their relationships to quantum algebra, which is a branch of algebra inspired by theoretical physics. She is also interested in tertiary education, and culture and inclusion in mathematics and STEM.

View More

You must confirm your public display name before commenting

Please logout and then login again, you will then be prompted to enter your display name.

Logout Read more 'Collective hum' of black holes could settle the debate over new physics    Our model of the universe is deeply flawed — unless space is actually a 'sticky' fluid    Scientists taught robots to swim through mazes using Einstein's relativity    How many holes does the human body have?    Our leading theory of dark matter may be wrong, huge new gravity study hints    'Proof by intimidation': AI is confidently solving 'impossible' math problems. But can it convince the world's top mathematicians?    Latest in Physics & Mathematics Scientists taught robots to swim through mazes using Einstein's relativity    'Collective hum' of black holes could settle the debate over new physics    Do you weigh more when an elevator goes up or when it comes down?    We now know why shoes squeak, and it involves miniature lightning bolts    Physicists recreated the first millisecond after the Big Bang — and found it was surprisingly soupy    'Proof by intimidation': AI is confidently solving 'impossible' math problems. But can it convince the world's top mathematicians?    Latest in News Webb telescope pushed to its limits by new look at 'city killer' asteroid 2024 YR4    Groundbreaking new drug shows promise for treating children with a devastating form of epilepsy    The sword in the sea: How one lucky graduate student found his second Crusader sword while taking a swim off Israel's coast    Climate disasters caused societal upheaval 3,000 years ago in China, study of 'oracle bones' hints    'Truly extraordinary': Mega-laser shooting at us from halfway across the universe is the brightest 'cosmic beacon' we've ever seen    NASA fixes Artemis II rocket for April launch to take astronauts around moon    LATEST ARTICLES

1. 1Webb telescope pushed to its limits by new look at 'city killer' asteroid 2024 YR4
2. 2Groundbreaking new drug shows promise for treating children with a devastating form of epilepsy
3. 3Scientists taught robots to swim through mazes using Einstein's relativity
4. 4The sword in the sea: How one lucky graduate student found his second Crusader sword while taking a swim off Israel's coast
5. 5Sodium-ion batteries are getting ready for prime time. How can they improve EVs?