Short Wave - 'Math In Drag' Explores The Creativity And Beauty In Numbers
Episode Date: June 7, 2024Kyne Santos was a student at the University of Waterloo when she began her math and her drag careers. She compares her double life to Hannah Montana, doing math equations at school by day and drag at ...night. You may already know Kyne from TikTok, where she makes educational videos about math, science, history and drag. And now, in her new book Math in Drag, Kyne explores the connections between math and drag: How both can be creative, beautiful and most of all, fun. Want to hear us cover more math? Email us at shortwave@npr.org. See pcm.adswizz.com for information about our collection and use of personal data for sponsorship and to manage your podcast sponsorship preferences.NPR Privacy Policy
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You're listening to Shortwave from NPR.
Kyn Santos was a student at the University of Waterloo when she began her math career and her drag career.
And I was like Hannah Montana at the time living a double life, you know, doing my math equations by day and doing the splits and some gay bar by night.
If you watched the first season of Canada's drag race, you know Kine.
Or maybe you're one of her 1.5 million followers on TikTok, where she makes educational videos about math.
science, history, and drag.
0.9 repeating equals 1.
Let's see a quick proof.
Let X equals 0.9 repeating.
Kainez always had a knack for math.
Her dad was an engineer.
And teachers were always telling her to enroll in math contests,
to challenge her skills.
You know, in math class,
the questions you're given on a test
are ones that your teacher prepared you for it.
But these math contests would have questions
that were a little bit more about problem solving.
And later in life,
she started doing those math videos on TikTok.
while dressed in drag.
I just thought it was camp, to be honest.
And then I got so many messages from people saying that they loved learning math through this fun, new lens.
I think that's when I realized that math is a drag queen.
You know, it's fabulous, it's mysterious, it can be controversial,
and there's a hidden universe underneath the surface.
And in her new book, Math in Drag, Kain explores those connections from the very first page,
which features a photo from her Catholic high school's Christmas concert in Canada.
She is lip-syncing to Lady Gaga's applause.
That performance was sort of my first time in drag.
It was half drag.
I was in full makeup, but no wig, sort of just leather pants, some combat boots.
It was what I called drag back then, just my way of sort of playing, experimenting with gender,
experimenting with makeup, and performing.
And you landed in the splits on the gymnasium floor?
Oh, yes, and everybody in that audience gagged.
So today on the show, the drag queen of math, as performed by kind.
How math can be mystical, creative, beautiful, and most of all, fun.
I'm Emily Kwong, and you are listening to Shortwave, the science podcast from NPR.
So the first chapter of your book is called Infinite Possibilities.
It blew my mind, honestly.
I never really thought deeply about infinity.
But you say that in equations, infinity is actually represented by something called a trans finite number.
And the trans finite number that represents infinity is alif null or l of zero.
Kind, how's this number used in math?
Like, break that down for me a little bit.
Yeah.
You know, when I was a kid, I used to have a girl at my class.
She'd say, kind, what's one plus one, two?
What's two plus two?
Four.
What's four plus four?
Eight.
And then she'd keep asking me questions like this and catch me once I couldn't come up with the answer.
And I think that was my first time realizing, yeah, the numbers really go on forever.
And I think we all have this intuitive notion of infinity as just a never-ending process.
But then it was Georg Cantor who said, actually, there are different levels of infinity.
And aliph null is actually the smallest level of infinity.
And alif null is the number of natural numbers.
So if you think one, two, three, four, five, all the whole numbers, those are all natural numbers.
And the number of natural numbers is, of course, infinite.
But that level of infinity is alif no.
Right.
The way that Cantor described it when he was, you know, trying to convince the world that there were different levels of infinities, he introduced this idea of matching.
So if you have, you know, two large groups and you want to see which group is larger, instead of counting them one by one,
and then comparing the numbers, you could match them up and pair them up.
And then in the end, you'll see if there's anybody left over.
That's how you can tell which group is larger.
And you did this with imagining an infinite number of drag queens
needing to be matched up with an infinite number of wigs, I believe.
Exactly. Exactly.
You know, if you have a huge group of drag queens and a huge group of wigs,
you say, each drag queen, go get one wig.
And then at the end, if you have more wigs left over,
then that means that you had a larger number of wigs.
And it showed that this is a mechanism we can use to compare two very large groups, even infinite groups.
Right.
In the example you provide, you're saying that basically you could have this infinite number of wigs and all numbered.
And if you were to remove the odd wigs, there would still be as many wigs as needed to match an infinite number of queens because that's how infinity works.
Like it never ever stops.
So you never have a problem with infinity.
And I don't know.
there's something kind of liberating about that idea.
Maybe it's just like the scarcity mindset of our day and age.
But when you are living in the world of infinity, there's always enough for everyone and everything can go around and every queen can be wigged.
Exactly.
You're right at the end.
It turns out that infinity is smaller than we thought it was, larger than we thought it could be, and queer than anyone ever imagined.
It doesn't follow rules in any way.
It has his own rules, which are not rules at all.
Yeah, and it's a great analogy to being a drag queen, being a human, and in the 21st century,
we're always breaking rules. And that's really the running theme throughout the whole book,
that math can break rules and math can be strange and mysterious. And we don't have it all
figured out, which is, I think, the complete opposite narrative that people are getting in school,
which is that math is all figured out. We know all the things.
The answer is that everything is either right or wrong and it's all black and white.
I want to look at the section that's called slaying uncertainty.
And you give so many examples of how a person can use probability to make calculated risks.
But you also write that, of course, life is always uncertain.
And that's kind of like fun and beautiful.
And like it's worth it to experiment without like saying to hell with probability, essentially some of the times.
How can we leverage the...
unpredictability and randomness in our lives using math?
Well, I think that's what's great about math is that it gives us the tool to say,
you know, I don't know what's going to happen today, but I can use math to sort of work out
what's likely to happen. And we, for most of human history, you know, we have been living
with, you know, rules of thumb. But math has just given us more precision. And with more
precision, we can take more calculated risks and get that error to be very small. I mean, you even
write in Chapter 7 illegal math, which I think was one of my favorite chapters of the whole book,
you write about how you're writing this book during a time when dozens of anti-drag bills and
measures were being introduced by politicians in more than 14 states in the U.S.
I mean, that added a layer of risk for sure.
I imagine, you know, coming out with this book at a time when, like, critique of drag is just
getting very, very loud.
Totally.
And listen, I mean, you bring up a great point.
And for me, sort of being a drag queen in this climate,
I'm weighing the risks of saying,
what's going to happen?
If I spend the next year or two trying to be a full-time drag queen,
the past couple of years, it's been scary.
And we've had lots of corporate sponsorships pulling out
and people sort of being scared to work with drag queens.
And so you have to sort of take a gamble,
because I don't know if this is going to be a sustainable career.
long term doing full-time drag.
Yeah. What do you feel like you want people to know about drag and those who are like afraid of
it or think it's somehow like dangerous? Like what do you wish they would understand? Especially
when you're up there like teaching math and science. I wish they would understand that it's just
fun. And it's just about not taking life so seriously, not taking gender expectations so
seriously, anybody who's been to a drag show knows it's just a fun concert of your favorite songs.
I recently was at doing a drag story time in Texas, and we had a group of protesters across the street,
which was my very first time being protested in person. And people have strange views about what
goes on in a drag show. And I just wish they would come in. I wish they would just read the book and
see for themselves what we're doing. You know, people.
think that we have this agenda and that we're all like getting in meetings talking about how we can
you know make this next generation of kids transition it's really not about that you know i could care less
if people want to be LGBT i want people to be themselves i want people to to to embrace the things
that we have in common instead of being scared of the things that we think the things that make us
different yeah absolutely and i suppose something you're doing throughout the book
really is pulling back the curtain on drag itself. How it works, how queens are judged based on
these tiny details, like the length of their gown and the height of their heels, how that is
constraining but can also spark creativity. I'm wondering, how do you see that show up in math,
like creativity within the rules? Yeah, you know, and people always think that math and drag are such
polar opposites. On one hand, you have a subject that's full of rules, and on the other hand,
you have a subject, drag, and drag is art, and art has no rules. But I think when you look a little bit
deeper under the surface, you see that they actually have a lot in common. On one hand, as you mentioned,
drag does have rules, or at least drag has standards and constraints. You know, drag queens want to
fit within a particular archetype of what you expect to see when you come to a drag show, which is,
you know, your lyrics and you are exaggerating gender with makeup and with costume.
But of course, drag queens also break the rules a little bit.
And math is like that too.
You know, math has constraints, and constraints don't necessarily have to be restrictive.
And sometimes the constraints are meant to be broken.
You know, our idea of what a number is is an example that I like,
because we used to think that numbers were just things you could count.
Yeah.
And then another level of abstraction beyond that is the idea of imaginary numbers and complex numbers and taking the square root of a negative number.
You know, you can encounter things like that and say, no, that doesn't fit my definition.
Yeah.
But maybe we can change the rules.
Maybe there are new types of numbers that we didn't know about before.
And maybe actually the rules need to expand to it to include these other types of numbers.
And every time that a mathematician changes the rules and questions what we,
we thought to be true. Math becomes all the more larger, all the more beautiful, all the more
powerful. Kine, happy Pride Month, and thank you so much for coming on Shortwave. Oh, thank you so
much. Well, thank you for having me. This episode was produced by Rachel Carlson and edited by
our showrunner, Rebecca Ramirez. It was fact-checked by Rachel and Rebecca. Gilly Moon was the
audio engineer. Beth Donovan is our senior director and Colin Campbell is our senior vice
president of podcasting strategy. I'm Emily Kwong. Thanks as always, Duterino.
for listening to Shorewave,
the science podcast from NPR.
