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# Intro to square roots

CCSS.Math:

Learn about the square root symbol (the principal root) and what it means to find a square root. Also learn how to solve simple square root equations.

## Want to join the conversation?

- How can you get the square root of 4? You can't do 1^2, right? Cause that just equals 1. Or am I doing it wrong?(37 votes)
- Square root of 4 is 2.

An easier way to solve the square root for small and simple numbers like 4 is to just see which number, when multiplied twice with itself come up with the number.

ex) Solve the square root of 9,

1 times 1 = 1

2 times 2 = 4

3 times 3 = 9.(7 votes)

- Is there such thing as a triangle root?(31 votes)
- There is no such thing as a triangle root, however, there is such a thing as a cube root, which would be somewhat the same idea. You will learn about cube roots a little later.(13 votes)

- If we consider square roots as real numbers then can it be further classified in both rational and irrational numbers? why we need negative root 9 = -3 as we can also write root 9= 3 as well as -3?(9 votes)
- Yes, square roots can create 2 answers -- the positive (principal) root and the negative root. When you are working with square roots in an expression, you need to know which value you are expected to use. The default is the principal root. We only use the negative root when there is a minus in front of the radical.

For example:

8 + sqrt(9) = 11

8 - sqrt(9) = 5(25 votes)

- so are we dividing a number by it self?(2 votes)
- No because if you divide a number by its self like 10 ÷ 10 then you would get 1 but the square root of 9 is 3 and if you were dividing a number by it's self then all the square roots would be 1.(5 votes)

- what is the square root of -1?(11 votes)
- There is no real number in existence that equals the square root of -1, so humans decided to create one, called
**i**. You can find more about imaginary numbers and i here: https://www.khanacademy.org/math/algebra2/introduction-to-complex-numbers-algebra-2/the-imaginary-numbers-algebra-2/v/introduction-to-i-and-imaginary-numbers(15 votes)

- This whole thing is kinda confusing for me. Can someone explain?(7 votes)
- The name kind of describes it. You’re basically finding the length of the side of a square if you know the area. For example, the square root of 121 is 11 because 11*11 is 121.(12 votes)

- Isn't a negative square root an imaginary number?(7 votes)
- Only if the minus sign is inside the square root.

sqrt(-9) creates the complex number 3i

-sqrt(9) just equals -3.

Hope this helps.(11 votes)

- What could you describe the difference between of Square root and Cube root?(8 votes)
- Cubing simply means multiplying by itself twice. If you think of a number as a line, then squaring gives you the surface area of the square with that line as its side. In that same way, we can construct a cube with side lengths of our initial number. Its volume is the "cube" of that initial number.

Once we get this, it's easy to reverse the process and understand the cube root: we take a number that represents the volume of a cube. When we construct the cube, the side length is the cube root of our number.

Therefore, if we take a number, construct the cube, and take its cube root, we get the original number back, which means we now can do this process both ways!(2 votes)

- Why do numbers have both a positive and a negative square root?(5 votes)
- Square roots can be both because the factors are the same number and same value, and also because positive*positive = positive squared and negative*negative = negative squared.(3 votes)

- Is there a difference between Principle and Perfect square roots?(5 votes)
- The Principal square root is normaly any square root with this symbol √. A Perfect square root is when the square root of a number is equal to an integer raised to an exponent = 2.

I.E. of a perfect square root: √9 = 3 because 3^2 = 9.

If you need more details, just comment :)

Hope this helped!(3 votes)

## Video transcript

- [Voiceover] If you're
watching a movie and someone is attempting to do fancy
mathematics on a chalkboard, you'll almost always see a
symbol that looks like this. This radical symbol. And this is used to show the square root and we'll see other
types of roots as well, but your question is, well, what does this thing actually mean? And now that we know a
little bit about exponents, we'll see that the square
root symbol or the root symbol or the radical is not
so hard to understand. So, let's start with an example. So, we know that three to
the second power is what? Three squared is what? Well, that's the same
thing as three times three and that's going to be equal to nine. But what if we went the other way around? What if we started with the nine, and we said, well, what times
itself is equal to nine? We already know that answer is three, but how could we use a
symbol that tells us that? So, as you can imagine,
that symbol is going to be the radical here. So, we could write the
square root of nine, and when you look at
this way, you say, okay, what squared is equal to nine? And you would say, well,
this is going to be equal to, this is going to be equal to, three. And I want you to really look at these two equations right over here, because this is the essence
of the square root symbol. If you say the square root of nine, you're saying what times
itself is equal to nine? And, well, that's going to be three. And three squared is equal
to nine, I can do that again. I can do that many times. I can write four, four
squared, is equal to 16. Well, what's the square
root of 16 going to be? Well, it's going to be equal to four. Let me do it again. Actually, let me start
with the square root. What is the square root of 25 going to be? Well, this is the number that
times itself is going to be equal to 25 or the number,
where if I were to square it, I'd get to 25. Well, what number is that, well, that's going to be equal to five. Why, because we know that
five squared is equal to, five squared is equal to 25. Now, I know that there's a nagging feeling that some of you might be having, because if I were to take negative three, and square it, and square
it I would also get positive nine, and the same
thing if I were to take negative four and I were
to square the whole thing, I would also get positive
16, or negative five, and if I square that I
would also get positive 25. So, why couldn't this thing
right over here, why can't this square root be positive
three or negative three? Well, depending on who you talk to, that's actually a reasonable
thing to think about. But when you see a
radical symbol like this, people usually call
this the principal root. Principal root. Principal, principal square root. Square root. And another way to think
about it, it's the positive, this is going to be the
positive square root. If someone wants the
negative square root of nine, they might say something like this. They might say the negative,
let me scroll up a little bit, they might say something like the negative square root of nine. Well, that's going to be
equal to negative three. And what's interesting
about this is, well, if you square both sides
of this, of this equation, if you were to square both
sides of this equation, what do you get? Well negative, anything negative
squared becomes a positive. And then the square root
of nine squared, well, that's just going to be nine. And on the right-hand side,
negative three squared, well, negative three times
negative three is positive nine. So, it all works out. Nine is equal, nine is equal to nine. And so this is an
interesting thing, actually. Let me write this a little
bit more algebraically now. If we were to write, if we were to write the principal root of nine is equal to x. This is, there's only one
possible x here that satisfies it, because the standard convention, what most mathematicians
have agreed to view this radical symbol as, is that this is a principal square root, this
is the positive square root, so there's only one x here. There's only one x that
would satisfy this, and that is x is equal to three. Now, if I were to write x
squared is equal to nine, now, this is slightly different. X equals three definitely satisfies this. This could be x equals
three, but the other thing, the other x that satisfies this is x could also be
equal to negative three, 'cause negative three squared
is also equal to nine. So, these two things,
these two statements, are almost equivalent,
although when you're looking at this one, there's two
x's that satisfy this one, while there's only one x
that satisfies this one, because this is a positive square root. If people wanted to write
something equivalent where you would have two
x's that could satisfy it, you might see something like this. Plus or minus square root
of nine is equal to x, and now x could take on positive
three or negative three.