Can magnetic dice really help someone cheat? Is this really a thing? How would that even work?
Though our handiwork isn't slick enough to fool a casino pit boss, a few experiments might help determine if magnetic dice are feasible. Let's cheat with magnetic dice!
We created six individual dice, each with a different sized magnet inside. We 3D printed the shapes, each with a cavity inside to hold a single cube magnet. With careful timing during the printing process, we inserted the magnet as the die was printed around it.
In each case, we inserted the magnet with the north pole facing the one, and the south pole facing the six. Each die had a subsequently larger magnet inside. The weakest has just a tiny, 3/16” B333 cube inside, whereas the largest is almost filled with the 1/2” B888 cube. Standard dice are sized as a 5/8” cube, so that last one is mostly magnet!
Before getting into anything fancy like a dice table rigged with an electromagnet, a more basic question has been on our minds. Would the magnet’s interaction with the earth’s magnetic field make one roll more likely than another?
The earth’s magnetic field points north, but also downward. Here in Pennsylvania, USA, the magnetic field is about 0.5 gauss, pointing north, but also at a downward angle of over 60 degrees. To learn more about that, see our earlier article, The Earth Is a Magnet.
The force from this magnetic interaction is weak. It's not enough to overcome the random bouncing around of a die, mostly. It's not going to force it to land on a six every time. Sometimes though, if the die is teetering on an edge, might this little magnetic force tip the balance more one way? In the long run, would we roll more sixes?
To test the theory, we rolled the dice. A lot. Each die was rolled by multiple people, totaling 480 recorded rolls for each die. Any tendency to roll more towards one number should show up. We guessed that we’d see this effect increase with increased magnet size/strength.
With 480 rolls of each die, we expect each individual number (1-6) to show up about 80 times. We wouldn’t expect the result to be exactly 80 rolls of each number, but it should be something fairly close.
The graphs of results show:
Why was three more likely? We're not sure, but it may have something to do with the 3D printing. All of our dice were printed on the printer's table with the three facing down. Would that affect it somehow? We're not sure.
It was a lot of fun making and testing these dice. There's one thing that doesn’t show up in the numbers: The weight isn’t right. The 3D printed plastic is lighter than regulation dice. The dice with big magnets are much heavier than regulation. If you let someone handle the big-magnet dice, they’ll know something is wrong very quickly.
The lightest magnet that gave us predictable results was the B666. This magnet weighs about 6.5g, which is quite a bit more than a regulation die of 4.1g. When you add the printed plastic, it’s nearly twice as heavy as normal.
With some magnetic dice to play with, it’s time to test the elephant in the room. What about a table with an electromagnet underneath? Can the house play unfairly with such a device?
If the dice is at all magnetic, then this has to be feasible. We noticed a difference in the rolls done in Earth’s relatively weak 0.5 gauss field. There has to be more influence if we increase the field strength on top of the table. What if the field were 30 times stronger?
That’s what we built. This dice table features a 5” diameter coil of 20 gauge wire. We had about 400 ft of wire to play with, which gave us 300 turns. We hooked it up to a 12V power supply, giving us about 0.6 Amps of current through the coil.
We wanted to make the coil twice as large, but ran out of wire!
Theoretically, we should see roughly 19 gauss at the center. That’s not a perfect theoretical analysis, but gets us in the ballpark. We measured about 15 gauss at the table surface, so close enough.
How effective is 15 gauss? Too much! In the center of the circle, the dice with the four largest magnets won’t stay down on any number adjacent to six. Set it down on a 2, 3, 4 or 5, and the dice will jump to display a 6. This is a little too obvious!
It will set down on a one, even if it’s unlikely to land on a one during a roll.
This is too strong to leave turned on all the time. Dice that land more often on one number will be easy to spot very quickly. A setup this strong would only be turned on occasionally to fool people, only getting the six for a key roll.
We didn't make it very large, but the coil could just as easily be much larger. It could be made as large as the table! We skipped this step because that would take a lot more wire, which can be expensive. For a proof-of-concept, we worked with materials at hand.
Please, do not cheat at dice. Don’t blame us for getting kicked out of a casino! We don’t promote making crooked dice. As always, this exploration was really just an excuse to play with magnets.
If you notice your dice stick to steel, though, somebody might be cheating.
We’ve heard from a number of customers who use strong neodymium magnets to create screens for car camping. Magnetically attached screens allow car campers to leave the windows open for ventilation while keeping bugs out.
Now that summer is here, we’ve run out of excuses. It’s time to make some of these screens for ourselves!
Powerful neodymium magnets are handy tools for relic hunters, treasure seekers, metal detector enthusiasts and more. We hear from many folks using our magnets for magnet fishing and more.
Let’s take a look at a few ways strong magnets can be useful. Follow along as we use powerful magnets to search lakes, old wells and help identify coins and silver.
We love talking about magnets. When we do, we often refer to magnetic field pictures to show what’s going on. There’s a lot of information to be learned from these images, but let's take a moment and examine just what they’re saying.
What are those black lines circling around the magnet? What do they mean? What are they telling us? Follow the path of a fluxline with us, journeying from pole to pole.
A few years ago, our Audio Speakers article featured some speakers made from plastic cups, coils of wire and magnets. They’ve never won any audio awards, but remain a popular demonstration. When we talk about how a current flowing through a wire in a magnetic field exerts a force, most of our audience starts drifting. Play some music through it, though, and suddenly everyone wants to know how it works!
We’ve enjoyed it how a simply constructed experiment highlights some electrical engineering basics in a way that even kids understand.
In this sequel article, we want to reverse what’s going on with those speakers. Can we make a microphone using a plastic cup?
Can placing magnets inside of your washing machine effectively clean your clothes, without using any laundry detergent? This is a question we get asked occasionally, but have never had a solid answer for.
There are some magnetic products out there that claim to wash your clothes without the use of laundry detergent. Simply stick the magnets to the drum of the washing machine and run your regular wash cycle.
We were skeptical of these claims so we wanted to conduct this experiment for ourselves. After all, Magnets Are Weird, right?