Why do mirrors flip left-and-right but not up-and-down?

If you’ve ever looked in a mirror, you’ve likely noticed that everything you see is flipped. When you raise your left hand, your reflection raises their right hand. When you wink with your right eye, your reflection’s left eye winks back. And if you write a message and hold it up, you’ll see your reflection hold up the identical sign, but everything appears backward, even the individual letters themselves. It appears that everything you see reflected in the mirror has their left-and-right reversed. But, for some reason, up-and-down don’t appear to be reversed. Your mirror reflection still has their feet on the ground, their ceiling up above, and all the letters on your mirror image’s writings aren’t flipped upside down, but remain right side up.

Why is this the case? It’s not just humans who experience this: whether you’re a sea star, an insect, a jellyfish, a parakeet or a cat — whether in space or on Earth or anywhere else in the Universe — you’ll still see the same thing. When you look into a mirror that’s mounted on any wall, they all appear to reverse left-and-right, but not up-and-down. This isn’t a deficiency in your mirror at all; it’s a consequence of how reflections work at a fundamental level.

When you reflect text in a mirror, both each letter and the letter order appear reversed. If the text can be read both ways, in reality and in the mirror, it’s known as a mirror ambigram.

The first thing you have to recognize is there’s nothing special about our environment here. There’s nothing remarkable, as far as mirrors and reflections go, about:

• our human eyes,
• our planet Earth,
• our gravitationally-based orientation of up-and-down,
• or the nature of light,

that has any effect on the outcome.

We could turn gravity on or off; we could rotate ourselves by any angle, even 45°, 90°, or 180° about any axis; we could give ourselves additional eyes or senses; we could rearrange the objects surrounding us in any configuration we like. Still, despite any of these modifications, we’d still see that up remained up, down remained down, and that everything in the mirror would appear as though left and right were switched.

One of the best examples to illustrate this is to consider a spinning ball in the mirror, and to consider it from two perspectives: one of a ball spinning about its vertical axis, like a basketball on an adept athlete’s finger, and one of a ball spinning about its horizontal axis instead.

From the perspective of Harlem Globetrotter TNT Lister, the balanced, spinning basketball appears to rotate from her left toward her right: the same as for the child on whose finger the ball is being transferred to, or counterclockwise. If this photograph instead were taken of TNT Lister’s mirror reflection, the ball would appear to be spinning in the opposite right-to-left (clockwise) direction instead.

When you spin a ball about its vertical axis, you can consider the fact that there are two ways to do it. Either, if you looked “down” at this ball from above, you’d see that it appeared to spin clockwise, from ahead to the right to behind to the left to ahead again, or counterclockwise, in the exact opposite direction.

If the ball is spinning clockwise, you can model that with your left hand. If you take your left hand and point your thumb up, you’ll notice that your fingers curl around in the clockwise direction. A clockwise-spinning ball follows this exact same orientation.

But now, take a look at the ball — and your left hand’s — reflection in the mirror. If you were to look “down” at that ball once again, from above, you’d see that it was rotating counterclockwise instead. If you followed the point on the ball that began closest to you, you’d see it move to your right and backward, away from you, then farther away and back to the center, then closer and toward the left, then closer still and back to the center. That counterclockwise motion could be described by your own right hand, showing how, once again, the mirror appeared to exchange left-for-right, while leaving the up-and-down direction unchanged.

A horizontally rotating basketball (left) and its mirror reflection. Not only does the text of the basketball appear flipped, from left to right, but the rotation of the basketball is now in the opposite direction about the same horizontal axis. Even though mirrors don’t exactly flip up-and-down, they don’t exactly flip left-and-right only, either.

What about if we then switched to spinning a ball about its horizontal axis? How would a mirror handle that?

Imagine that you’re holding the ball in front of you so that it’s sandwiched between your two index fingers that are pointing toward one another. We again have two choices of how to rotate it, so let’s pick one: overhand and away from you. If we start at the point on the ball closest to your body’s core, you’ll see it move:

• up and away from you,
• then back down toward the middle but still away from you,
• then further down away from the middle and back toward you,
• and then back up toward the middle and toward you,

whereupon it returns to its initial position. This “underhand” rotation was one choice you could have made; the reverse of it would lead to an “overhand” rotation instead. (If you’ve ever been part of an argument on which way is the “proper” way to hang a toilet paper roll, you’ll recognize these two visualizations.)

But this time, when you look in the mirror, what’s happening? Left and right are the same. Up and down are the same. But the ball? The mirrored version of the ball, instead of appearing to spin with an underhand rotation, appears to be spinning with an overhand orientation.

If the woman in the picture moves toward the mirror, her ball will rotate counterclockwise from the camera’s perspective, while the mirror image of her ball will appear to rotate clockwise. If you traced any imaginary point on the ball as she moved, you’d be able to trace out exactly how the motion of the objects in the mirror differed from objects in the real world.

This example surprises most people. Sure, it’s clearly symmetric about the vertical axis; if you were to draw an imaginary line down your center, with the ball rotating about its horizontal axis, it’s clear that the left half of yourself and the right half are completely symmetric. Same with your reflection in the mirror: left and right appear completely symmetric.

Sure, your mirror is still replacing your left with your right. Your reflection’s right hand corresponds to your left hand; your reflection’s left hand corresponds to your right. From the perspective of your reflection, their ball is doing the same thing that your ball is from your own perspective, moving up and away from their body, then down and away, then down and toward, and then up and toward, returning to its initial position.

But if they see their ball spinning “underhand” from their perspective, yours appears to spin “overhand” from their perspective. The mirror appears to be flipping the rotational direction of that ball as well.

As a ball spins about a horizontal axis, its reflection spins as well. However, regardless of which perspective you choose, there will be something that’s flipped dependent on whether you examine the actual object or the mirrored reflection: what’s closer or farther, or moving toward or away from you.

There’s a very powerful clue as to what’s going on with mirrors from this example, if we’re clever enough to identify it. Imagine — and we can imagine anything we like in this example — that the ball that’s spinning about its horizontal axis is now transparent. What we’re going to do is to create a single point on this ball, right along its equator, that we can track, as though we took a permanent marker and drew a point on a ball that was made of clear glass.

Now, from our perspective in the real Universe, we’re going to track the position of both our dot and the dot that appears in the mirror. Simultaneously, starting with the dot positioned closest to our own body, what we see is as follows:

• the real dot begins closest to us and farthest from the mirror, and so the mirrored dot begins farthest from us from our perspective,
• then the real dot rises up and gets farther away from us but closer to the mirror, whereas the mirrored dot rises up and gets closer to us,
• then, after reaching its maximum height, the real dot descends while reaching its most distant point from us but closest to the mirror, while the mirrored dot similarly descends while reaching its closest point to us,
• then the real dot starts to return closer to us while it descends, moving farther from the mirror, while the mirrored dot continues its descent and moves back away from us,
• and then the real dot, after reaching its minimum elevation, rises once again, getting closer to us (and farther from the mirror) until it returns to its original position, while the mirrored dot rises similarly, retreating farther from us and farther from the mirror until it returns to its initial position as well.

A meson, a composite particle, spins about its axis before it decays. When mesons decay, they emit electrons along a particular axis and in a particular direction. Certain mesons are right handed: if you curl your fingers in the direction of the meson’s rotation, the electron will preferentially be emitted in the direction your right thumb points. The Universe in the mirror, however, possesses the opposite “handedness” to our own.

Left and right, as you can see, play absolutely no role in this example. We’re just looking at a single point that moves up-and-down while also moving forward-and-backward. When the real dot appears to move up, the mirrored dot appears to move up. When the real dot appears to move down, the mirrored dot appears to move down. There is no flipping of up-and-down here.

But there isn’t a flipping of left-and-right, either!

If you were to perform the same experiment with a clear glass ball and a drawn-on dot, but rotated the ball around its vertical axis instead of its horizontal axis, you’d notice that:

• when your dot moved to the left, the mirrored dot moves to the left,
• when your dot moved back to the center, the mirrored dot moves to the center,
• when your dot moved to the right, the mirrored dot moves to the right,
• and when your dot returns to the center, the mirrored dot also returns to the center.

Something is happening, clearly, but it isn’t that left-to-right is getting reflected, either.

We typically see text reflected left-to-right in a mirror because those mirrors are mounted on vertical surfaces. If we instead mounted a mirror on a horizontal surface, such as above a “fire exit” sign, we’d see the text reflected up-to-down instead of left-to-right. However, mirrors don’t actually reflect either up-and-down or left-and-right; what you see depends on their orientation.

And yet, mirrors really are reflective surfaces. They don’t switch up-and-down but they also don’t switch left-and-right. Instead, what mirrors do is they reflect back-to-front: the third (depth) dimension!

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Think about what happens when you look at yourself in the mirror. Light — even though it’s ambient light reflected off your body from elsewhere in the room — comes from every part of you. There’s no perspective from which you’re invisible, and hence that light must be radiating outward in all directions.

The only way you can ever see anything is if light enters your eyes, just like the only way a camera, telescope, or other observer can see anything is if photons (or light rays) interact with it at a particular location: a specific time and place. So if we want to know what you’re going to see and where you’re going to see it, all you need to do is trace out the light rays: from whatever part of your body they’re emitted from, reflected off the mirror (obeying the physical laws that govern optics), and ending at your eyes. Based on the total distance the light travels and the angle it comes in at, that’s where your eyes and brain infer the “image” in the mirror to be.

When you look at your reflection in a mirror, you see your sides reversed from one another. When you hold up your left hand, your reflection in the mirror holds up their right hand. When you wink your right eye, your reflection winks their left eye. And when you move something farther away from you, your reflection moves that object closer to you here on the other side of the mirror. Optics holds the reason why.

If your body were partially transparent, allowing you to see inside your reflection’s body, you’d find that everything was flipped front-to-back. Your left hand, when you hold it up, appears as though your fingernails are closer to you, your palm is farthest from you, your thumb is on the right, and your fingers are pointing up. That’s what a left hand looks like.

But in the mirror, that same hand has its fingernails farthest from you, its palm is closest to you, its thumb is on the right, and its fingers are pointing up. That’s exactly what you’d see if you held your (real) right hand up but with your palm facing your face instead. In the mirror:

• a left hand becomes a right hand,
• writing gets flipped to be “mirrored” writing,
• objects that spin clockwise appear to spin counterclockwise,
• and vice versa on everything above.

But the reason is not because mirrors flip things left-to-right; they don’t. Instead, they flip things front to back, and that’s the explanation for what we see.

The writing in this image appears the same way writing appears in a mirror. However, this isn’t a reflection of text that’s being shown here, but rather the opposite side of a transparent surface: you’re seeing the writing from the back instead of from the front. Mirrors don’t flip up-and-down or left-and-right, but rather front-and-back, and how it’s mounted determines the rest.

In physics, there’s a special type of symmetry that exists if what happens in the mirror is indistinguishable from what happens in reality: parity symmetry. Most of the laws of physics respect this symmetry, but not all of them. In particular, whenever you have a radioactive decay, you’re at risk of violating this symmetry, since particles have a spin, a spin axis, and a decay direction, the same way your hands have a direction that your fingers curl and a direction that your thumb points. Right hands and left hands are fundamentally different — just like chiral molecules are different from one another — and so are spinning particles that have a decay direction. For those that do, parity is violated, the same way a right-handed person’s reflection appears to be left-handed instead.

What’s remarkable about the way mirrors work is that they’re completely independent of the observer. If our eyes were separated in the vertical direction rather than the horizontal direction, mirrors would still reflect front-to-back. If we were in zero-gravity, if we had only one eye, if we were a rotationally symmetric starfish, etc., it wouldn’t change what we see in the mirror at all. The only difference is that things are reflected front-to-back, and that changes the “handedness” of everything that appears in the mirror, irrespective of how we view it.