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Starts With A Bang

Throwback Thursday: The Physics Of Fireworks

The anatomy and science of what’s required for such a spectacular show.

“Celebrate the independence of your nation by blowing up a small part of it.” –Summer of 4 ft. 2; The Simpsons

For those of you who aren’t from the U.S. or U.K., this coming Saturday is the day that my nation celebrates the birth of its independence by rebelling against Great Britain. (That is to say, successfully rebelling against Great Britain. I’m looking at you, Australia!)

The most common way to celebrate our Independence Day? Literally, by blowing up a small part of it. I’m referring to the tradition of fireworks.

Image credit: © Copyright 2005–2015 Capital Concerts, Inc.

How do they work? Anytime you ask the question of “how” and you refer to a physical phenomenon, you’re asking a question custom-made for science!

You start with three simple ingredients: sulfur, charcoal, and a source of potassium nitrate. Charcoal, in this case, is not the briquettes you use on your grill, which often contain no actual charcoal, but is the carbon residue left behind by organic matter (like wood) once it has been charred (or pyrolyzed), having had all the water removed. Potassium nitrate is found in sources like bird droppings or bat guano. Take a mortar and pestle, mix them together, and what you’ll get is a fine, black powder.

Image credit: the ingredients for the very basics of a firework, or how to make gunpowder. From Ulrich Bretscher of

Gunpowder, in fact. All you need now is some oxygen — readily found in the potassium nitrate source (which means fireworks will even work on planets without oxygen in their atmosphere) — and a small source of heat. For the heat, so little is needed that even a lit match will do.

What happens when you put it all together?

Image credit: Francisco Schmeda Ochipinti of flickr, via

The good news is, you’ll get an explosion, accompanied by a deafening “boom” sound. But as much fun as that is, a simple explosion is hardly a firework! Sure, it’s part of a firework, but the real deal requires so much more.

After all, if you’ve ever seen one, you know that the four major things that make a good firework are height, size, shape and color. The explosion itself is the catalyst for the latter three, but that’s just the starting point. As it turns out, physics has something to say about each one of these: the height, the size, the shape and the color of your firework!

The height is the easiest one to explain, so let’s start there.

Image credit: NOVA Online, via

The way you launch a firework is basically the same way you launch a cannonball out of a cannon! You put a “lift charge” in between the actual firework and the bottom of a strong, closed tube/pipe, and ignite it, propelling the firework up.

How high you want it to go is dependent only on the initial velocity of your firework, which is almost always larger for bigger fireworks. A small fireworks show might have 2″ (5 cm) to 6″ (15 cm) diameter shells being launched, which reach a height of anywhere from 200 to maybe 500 feet (60–150 m). But a very large fireworks show, like the one that takes place by the Statue of Liberty in New York City every year, uses fireworks with shells up to two or three feet in diameter (up to nearly a meter), and those fireworks often reach altitudes of well over 1,000 feet (300 meters).

Image credit: Leo of fwallpapers, via

Once the initial launch happens, the fuse on the actual firework itself — if all goes properly — is now lit, and burns as it goes up. For both aesthetic and safety reasons, you launch the larger fireworks to a higher altitude. (Aesthetics because more people can see them at higher altitudes; safety because, well, there’s “fire” right there in the name for a reason!)

The physics plays a central role with the size of your fireworks as well, because a larger firework not only requires a larger lift charge, but a larger explosive charge to propel the insides outward! The amount of the lift charge that you use has to be sufficient to launch the firework to the necessary altitudes described above, and that explains why larger fireworks get launched to higher altitudes.

Images credit: Thinkquest (2011); discontinued 2013 via

So long as they’re not “duds” (i.e., so long as the fuse ignites and burns properly), your firework will explode at or near the apex of their flight. The higher ones are usually larger, resulting in, well, aesthetically-pleasing (and again, safer) fireworks displays. But what determines their spectacular shapes that they come in? To find that out, we need to go inside the anatomy of a firework.

Image credit: the three basic types of firework; original source unknown.

Fireworks come in many different styles, but the two important elements, once your firework has been launched into the air with its fuse lit, are the burst charge and the stars.

The burst charge can be as simple as more gunpowder, or it could be a more complicated (or even a multi-stage) explosive. The stars, on the other hand, are what actually go off in many directions, producing the beautiful display we’re all so accustomed to seeing. When the fuse burns down to the point where the flame reaches the burst charge, the charge ignites!

This ignition, depending on how the firework is put together in the first place, will send the stars off into whatever pattern or direction it was designed for.

Image credit: Bev & Lyle at TravelPod.

When the burst occurs, the temperatures get so hot that the individual stars that were contained inside ignite. This is where — for me — the most interesting part of the fireworks happens.

Travel the Universe with astrophysicist Ethan Siegel. Subscribers will get the newsletter every Saturday. All aboard!

In addition to whatever (optional) propulsion or fuel exists inside these stars, such as the ability to make them spin, rise, or thrust in a random direction, the stars are also the source of the light and color we find in our fireworks.

Image credit: DarkMyRoad of

How are these “stars” responsible for color? Although there are some recent advances (covered in excellent detail by Janet Stemwedel back in 2007), the simplest explanation is that different elements and compounds have different characteristic emission lines. For example, if you take some sodium and heat it up, it emits a characteristic yellow glow, because of its two very narrow emission lines at 588 and 589 nanometers. (You’re probably familiar with them from sodium street lamps.)

Image credit: Sooz of Pixdaus, via

We have a great variety of elements and compounds that emit a great variety of colors! Different compounds of Barium, Sodium, Copper and Strontium can produce colors covering a huge range of the visible spectrum, and the different compounds inserted in the fireworks’ stars are responsible for everything we see. Some notable ones are shown below in chromaticity space.

Image credit: Reema Gondhia, via

And that’s how fireworks work, from launch, up to the proper height, to their explosion, to the size, pattern, and color of the spectacular show they put on! The only thing we didn’t cover, of course, is the “BOOM” sound that they make. But that’s the simplest thing of all!

The “blast” from the explosion of gunpowder creates an outward moving pressure wave. At the front of this wave, this pressure reaches very high levels, many times that of the normal atmosphere. The “boom” you hear is simply the rapid change in pressure in the air, which is all that sound — a pressure wave — really is.

Image credit: Jearl Walker of Flying Circus of Physics, via

And that’s the physics of fireworks! Now, go enjoy the show, and have a great (and safe) holiday, however you celebrate it!

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