A wave is any thing that changes the average. Like the ocean is still until wind blows and it creates a wave, moving water up and down towards a direction. Light, radio, gamma, Wi-Fi, UV, Bluetooth etc. are all part of the electromagnetic spectrum. Which is, to simplify, a wave that has its own energy packets called photons. So depending on the frequency of the wave, they can either be massive, like radio waves, or small like gamma. Wi-fi, which is a microwave is in between. So when moving in the physical space, a larger wave would have more interference (like when you turn on a radio and you hear the fuzz or how old TVs had noise) but but since its a low frequency wave, it carries less energy. On the flip side, a higher frequency would carry more energy and information but for a shorter range before it becomes a longer wave then interference becomes are problem. (Interference can be anything…for radio it can be a mountain, particles in the wind, humidity etc. for microwaves it can be a thick wall, a person etc. also the waves are small so they can go in between atoms and their energy level is low enough that it doesn’t affect atomic structures.

Also the thing that travels is a photon when you look close, but its a wave when you zoom out. Wave-particle duality did a number to a lot of physicists. Also! It doesn’t need a medium. The wave moves faster in a vacuum.

(A photon is a massless particle that is a unit of energy. And it moves at the speed of light (which is also a photon).

A wave is any thing that changes the average. Like the ocean is still until wind blows and it creates a wave, moving water up and down towards a direction. Light, radio, gamma, Wi-Fi, UV, Bluetooth etc. are all part of the electromagnetic spectrum. Which is, to simplify, a wave that has its own energy packets called photons. So depending on the frequency of the wave, they can either be massive, like radio waves, or small like gamma. Wi-fi, which is a microwave is in between. So when moving in the physical space, a larger wave would have more interference (like when you turn on a radio and you hear the fuzz or how old TVs had noise) but but since its a low frequency wave, it carries less energy. On the flip side, a higher frequency would carry more energy and information but for a shorter range before it becomes a longer wave then interference becomes are problem. (Interference can be anything…for radio it can be a mountain, particles in the wind, humidity etc. for microwaves it can be a thick wall, a person etc. also the waves are small so they can go in between atoms and their energy level is low enough that it doesn’t affect atomic structures.

Also the thing that travels is a photon when you look close, but its a wave when you zoom out. Wave-particle duality did a number to a lot of physicists. Also! It doesn’t need a medium. The wave moves faster in a vacuum.

(A photon is a massless particle that is a unit of energy. And it moves at the speed of light (which is also a photon).

Unfortunately the real answer to your question is a bit long, because electromagnetic waves are different than any other kind of wave you are used to, in that there is no medium that the wave is traveling through, like water or air. They can even travel through empty space. But I will do my best.

Electricity and magnetism are related in an interesting way. If you run electric current through a wire near a compass, you’ll cause the compass to change direction. If you spin a magnet near a coiled wire, you will cause an electric current in the wire. They are related to each other, but in a strange, physically perpendicular way you’d never really guess on your own.

Hold your right hand out like you were making a finger gun. Pew pew. But now, also half-extend your middle finger to point to the left. Your thumb, index finger, and middle finger form a 3-way x/y/z axis. This is how electricity, magnetism, and physical force are related: a magnetic field in the direction of your index finger causes an electric charge in the direction of your middle finger, and both together cause a force in the direction of your thumb.

Now imagine you could sort of “grab” a little bit of empty space, and “pull” a bit of electric charge in one direction from nothing, with no physical object there. Almost like you were stretching a virtual rubber band. This would create a magnetic charge rubber band stretching the same amount, in a perpendicular direction. Now let go.

What’s interesting is that these two stretched rubbed bands kind of “tug” on each other, wanting to get back to neutral. So the perpendicular electric and magnetic forces pull each other back towards zero, but there’s nothing to stop them when they get there, so they keep going right past each other and end up stretching back out the same distance, but in the opposite direction, as from where they started.

Now they pull on each other again, back to zero, and again right past each other. Back and forth, back and forth. There is no “friction” to slow them down, so they are a permanently oscillating little bit of electricity and magnetism. How fast do they oscillate? Well, depends how far you stretched the little rubber bands to begin with. The more you stretched them, e.g. the more energy you put into creating your little packet to start with, the faster they snap back and forth.

But remember your little finger gun: the result of this oscillation between your index finger (magnetic) and ring finger (electric) directions results in a force in the direction of your thumb.

Meaning, your oscillating little “packet” of electric and magnetic rubber bands experiences a force, and it *moves.* How fast does it move? Well, it has no mass, remember. It has no inertia, ‘cuz it’s not made of “stuff.” So it moves as fast as anything in this universe can: the speed of light.

So it is a distinct little packet of energy that is moving through space like a bullet. But that packet is made up of oscillating electric and magnetic fields. The rate of the oscillation depends on how much energy created it to begin with. How much the rubber bands were stretched before you let go. But no matter how fast they oscillate, they still travel through space at the same speed of light. High energy packets will travel less distance before they return to their initial configuration. Lower will travel further. This is the “wavelength” that differentiates wifi, from visible light, from radio, or gamma rays.

[Here’s an attempt at showing this animated.](https://commons.wikimedia.org/wiki/File:EM-Wave.gif)

It’s very hard to actually draw this, as it’s a 3D thing with stuff wiggling along 2 axes while traveling in a third. So most depictions of electromagnetic waves simplify it significantly, as a static 2D squiggle on paper. And because the actual explanation is a whole lot longer and requires knowing about the relationship between electricity and magnetism (see length of above), most grade school science books just say “eh, close enough” and move on. Unfortunately, that simplification tends to cause the same confusion you have.

Unfortunately the real answer to your question is a bit long, because electromagnetic waves are different than any other kind of wave you are used to, in that there is no medium that the wave is traveling through, like water or air. They can even travel through empty space. But I will do my best.

Electricity and magnetism are related in an interesting way. If you run electric current through a wire near a compass, you’ll cause the compass to change direction. If you spin a magnet near a coiled wire, you will cause an electric current in the wire. They are related to each other, but in a strange, physically perpendicular way you’d never really guess on your own.

Hold your right hand out like you were making a finger gun. Pew pew. But now, also half-extend your middle finger to point to the left. Your thumb, index finger, and middle finger form a 3-way x/y/z axis. This is how electricity, magnetism, and physical force are related: a magnetic field in the direction of your index finger causes an electric charge in the direction of your middle finger, and both together cause a force in the direction of your thumb.

Now imagine you could sort of “grab” a little bit of empty space, and “pull” a bit of electric charge in one direction from nothing, with no physical object there. Almost like you were stretching a virtual rubber band. This would create a magnetic charge rubber band stretching the same amount, in a perpendicular direction. Now let go.

What’s interesting is that these two stretched rubbed bands kind of “tug” on each other, wanting to get back to neutral. So the perpendicular electric and magnetic forces pull each other back towards zero, but there’s nothing to stop them when they get there, so they keep going right past each other and end up stretching back out the same distance, but in the opposite direction, as from where they started.

Now they pull on each other again, back to zero, and again right past each other. Back and forth, back and forth. There is no “friction” to slow them down, so they are a permanently oscillating little bit of electricity and magnetism. How fast do they oscillate? Well, depends how far you stretched the little rubber bands to begin with. The more you stretched them, e.g. the more energy you put into creating your little packet to start with, the faster they snap back and forth.

But remember your little finger gun: the result of this oscillation between your index finger (magnetic) and ring finger (electric) directions results in a force in the direction of your thumb.

Meaning, your oscillating little “packet” of electric and magnetic rubber bands experiences a force, and it *moves.* How fast does it move? Well, it has no mass, remember. It has no inertia, ‘cuz it’s not made of “stuff.” So it moves as fast as anything in this universe can: the speed of light.

So it is a distinct little packet of energy that is moving through space like a bullet. But that packet is made up of oscillating electric and magnetic fields. The rate of the oscillation depends on how much energy created it to begin with. How much the rubber bands were stretched before you let go. But no matter how fast they oscillate, they still travel through space at the same speed of light. High energy packets will travel less distance before they return to their initial configuration. Lower will travel further. This is the “wavelength” that differentiates wifi, from visible light, from radio, or gamma rays.

[Here’s an attempt at showing this animated.](https://commons.wikimedia.org/wiki/File:EM-Wave.gif)

It’s very hard to actually draw this, as it’s a 3D thing with stuff wiggling along 2 axes while traveling in a third. So most depictions of electromagnetic waves simplify it significantly, as a static 2D squiggle on paper. And because the actual explanation is a whole lot longer and requires knowing about the relationship between electricity and magnetism (see length of above), most grade school science books just say “eh, close enough” and move on. Unfortunately, that simplification tends to cause the same confusion you have.

Unfortunately the real answer to your question is a bit long, because electromagnetic waves are different than any other kind of wave you are used to, in that there is no medium that the wave is traveling through, like water or air. They can even travel through empty space. But I will do my best.

Electricity and magnetism are related in an interesting way. If you run electric current through a wire near a compass, you’ll cause the compass to change direction. If you spin a magnet near a coiled wire, you will cause an electric current in the wire. They are related to each other, but in a strange, physically perpendicular way you’d never really guess on your own.

Hold your right hand out like you were making a finger gun. Pew pew. But now, also half-extend your middle finger to point to the left. Your thumb, index finger, and middle finger form a 3-way x/y/z axis. This is how electricity, magnetism, and physical force are related: a magnetic field in the direction of your index finger causes an electric charge in the direction of your middle finger, and both together cause a force in the direction of your thumb.

Now imagine you could sort of “grab” a little bit of empty space, and “pull” a bit of electric charge in one direction from nothing, with no physical object there. Almost like you were stretching a virtual rubber band. This would create a magnetic charge rubber band stretching the same amount, in a perpendicular direction. Now let go.

What’s interesting is that these two stretched rubbed bands kind of “tug” on each other, wanting to get back to neutral. So the perpendicular electric and magnetic forces pull each other back towards zero, but there’s nothing to stop them when they get there, so they keep going right past each other and end up stretching back out the same distance, but in the opposite direction, as from where they started.

Now they pull on each other again, back to zero, and again right past each other. Back and forth, back and forth. There is no “friction” to slow them down, so they are a permanently oscillating little bit of electricity and magnetism. How fast do they oscillate? Well, depends how far you stretched the little rubber bands to begin with. The more you stretched them, e.g. the more energy you put into creating your little packet to start with, the faster they snap back and forth.

But remember your little finger gun: the result of this oscillation between your index finger (magnetic) and ring finger (electric) directions results in a force in the direction of your thumb.

Meaning, your oscillating little “packet” of electric and magnetic rubber bands experiences a force, and it *moves.* How fast does it move? Well, it has no mass, remember. It has no inertia, ‘cuz it’s not made of “stuff.” So it moves as fast as anything in this universe can: the speed of light.

So it is a distinct little packet of energy that is moving through space like a bullet. But that packet is made up of oscillating electric and magnetic fields. The rate of the oscillation depends on how much energy created it to begin with. How much the rubber bands were stretched before you let go. But no matter how fast they oscillate, they still travel through space at the same speed of light. High energy packets will travel less distance before they return to their initial configuration. Lower will travel further. This is the “wavelength” that differentiates wifi, from visible light, from radio, or gamma rays.

[Here’s an attempt at showing this animated.](https://commons.wikimedia.org/wiki/File:EM-Wave.gif)

It’s very hard to actually draw this, as it’s a 3D thing with stuff wiggling along 2 axes while traveling in a third. So most depictions of electromagnetic waves simplify it significantly, as a static 2D squiggle on paper. And because the actual explanation is a whole lot longer and requires knowing about the relationship between electricity and magnetism (see length of above), most grade school science books just say “eh, close enough” and move on. Unfortunately, that simplification tends to cause the same confusion you have.

Electromagnetic waves have very weird motion because if you take a “drop” of electrical field and then “throw” it, it’ll generate magnetic fields in a corkscrew motion around it as it picks up speed.

Likewise, a “drop” of magnetic field, when “thrown” will generate electric fields in a corkscrew motion around the magnetic field.

Electro magnetic waves travel because whenever an electric field speeds up, it’ll create a speeding up magnetic field which creates a speeding up electric field which creates a speeding up magnetic field which creates…

Imagine a sheet of electric field moving to the right this will generate a sheet of magnetic field in front of it which moves up. That will generate a sheet of electric field in front of it moving left. That will generate a sheet of magnetic field in front of it moving down. So as the wave moves forward, you get electric fields moving left and right and magnetic fields moving up and down. Note that the movement of the electric and magnetic fields are never in the same direction as each other, or the wave’s motion.

“Wait, where did the corkscrew motion go when we switched to moving sheets?” Imagine that an electric field sheet is just a bunch of electric field “drops” thrown together, all right next to each other. Now, the corkscrewing magnetic fields all overlap and the corkscrews cancel out into a sheet.

Electromagnetic waves have very weird motion because if you take a “drop” of electrical field and then “throw” it, it’ll generate magnetic fields in a corkscrew motion around it as it picks up speed.

Likewise, a “drop” of magnetic field, when “thrown” will generate electric fields in a corkscrew motion around the magnetic field.

Electro magnetic waves travel because whenever an electric field speeds up, it’ll create a speeding up magnetic field which creates a speeding up electric field which creates a speeding up magnetic field which creates…

Imagine a sheet of electric field moving to the right this will generate a sheet of magnetic field in front of it which moves up. That will generate a sheet of electric field in front of it moving left. That will generate a sheet of magnetic field in front of it moving down. So as the wave moves forward, you get electric fields moving left and right and magnetic fields moving up and down. Note that the movement of the electric and magnetic fields are never in the same direction as each other, or the wave’s motion.

“Wait, where did the corkscrew motion go when we switched to moving sheets?” Imagine that an electric field sheet is just a bunch of electric field “drops” thrown together, all right next to each other. Now, the corkscrewing magnetic fields all overlap and the corkscrews cancel out into a sheet.

Electromagnetic waves have very weird motion because if you take a “drop” of electrical field and then “throw” it, it’ll generate magnetic fields in a corkscrew motion around it as it picks up speed.

Likewise, a “drop” of magnetic field, when “thrown” will generate electric fields in a corkscrew motion around the magnetic field.

Electro magnetic waves travel because whenever an electric field speeds up, it’ll create a speeding up magnetic field which creates a speeding up electric field which creates a speeding up magnetic field which creates…

Imagine a sheet of electric field moving to the right this will generate a sheet of magnetic field in front of it which moves up. That will generate a sheet of electric field in front of it moving left. That will generate a sheet of magnetic field in front of it moving down. So as the wave moves forward, you get electric fields moving left and right and magnetic fields moving up and down. Note that the movement of the electric and magnetic fields are never in the same direction as each other, or the wave’s motion.

“Wait, where did the corkscrew motion go when we switched to moving sheets?” Imagine that an electric field sheet is just a bunch of electric field “drops” thrown together, all right next to each other. Now, the corkscrewing magnetic fields all overlap and the corkscrews cancel out into a sheet.

An easy way to think about it is that it’s light on a spectrum you can’t see with your eyes.

An easy way to think about it is that it’s light on a spectrum you can’t see with your eyes.