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### Course: Algebra (all content) > Unit 11

Lesson 6: Simplifying square roots# Simplifying square roots review

Learn how to rewrite square roots (and expressions containing them) so there's no perfect square within the square root. For example, rewrite √75 as 5⋅√3.

## Simplifying square roots

### Example

Let's simplify $\sqrt{75}$ by removing all perfect squares from inside the square root.

We start by factoring $75$ , looking for a perfect square:

We found one! This allows us to simplify the radical:

So $\sqrt{75}=5\sqrt{3}$ .

*Want another example like this? Check out this video.*

## Simplifying square roots with variables

### Example

Let's simplify $\sqrt{54{x}^{7}}$ by removing all perfect squares from inside the square root.

First, we factor $54$ :

Then, we find the greatest perfect square in ${x}^{7}$ :

And now we can simplify:

## More challenging square root expressions

*Want to try more problems like these? Check out this exercise.*

## Want to join the conversation?

- what grade maths would this be?(17 votes)
- I think it’s about eighth or ninth grade. But people take math at different times. I’ve known fith graders who have taken algebra and geometry in the same year, and I’ve known ninth graders who have taken algebra. Even if you’re taking algebra in ninth grade, that’s okay. What really matters is that you understand the content when you learn it.(70 votes)

- when will we ever use this in everyday life? whats the point of even learning this?(15 votes)
- Jaidyn,

After learning this helps you pass your Math class and graduate high school, there are many careers where this is used. Most obviously, it's used in engineering and computer science. However, when I worked in construction, I used to use square roots regularly to determine whether items would fit through a doorway on a diagonal. (Note: this also involves trigonometry.)(54 votes)

- Anyone else need to take like 4 or 5 hours to really get a firm understanding of this lesson? or am I just dumb?(17 votes)
- Sometimes things snap right into place and the light goes on right away, and other times we need review and practice. If you got this far, you already have all the pieces you need to work with radicals. It's a matter of seeing how they go together.(9 votes)

- golly gracious i think ive passed out 15 times trying to these(20 votes)
- can a fraction be an exponent?(10 votes)
- A fraction can be an exponent. When a fraction is an exponent, you can change it so that a there is a first, second, third, etc. root of something.

For example,

1^1/2 = square root of 1

1^1/3 = third root of 1

1^1/4 = fourth root of 1

And so on and so forth. This was covered in a series of videos in the topic Rational Exponents and Radicals.

https://www.khanacademy.org/math/algebra/rational-exponents-and-radicals/alg1-rational-exp-eval/v/fractional-exponents-with-numerators-other-than-1(15 votes)

- In the video "Simplifying square roots (variables)" @1:40Sal explains "as I said in the last video, the principal root of X squared is going to be the absolute value of X, just in case X is a negative number". I have two questions:

(1) Can anybody please point me to that video? I can't find it.

(2) I don't understand the need for an absolute value. If we state, before beginning to solve the problem, that the domain of the X variable is the Positive Real Numbers (or X greater than or equal to zero), aren't we already cancelling out the possibility that the X variable assumes a negative value by restricting the domain, thus rendering the use of the absolute value unnecessary?(11 votes) - what about problems with a number already multiplying the square root. Do you multiply or add the numbers together?(5 votes)
- It's easier to understand if there is an example. Let's say you have √98. 98 is 49*2 which is 7^2*2, it would be 7√2. If you have 2√98. √98 is 7√2, 2√98 would be 14√2.

Hope this helps! If you have any questions or need help, please ask! :)(9 votes)

- Can i also simplify √72 in this way: √72 = √9*8 = √9*√8 = 3√8

instead of: √72 = √2*36 = √36*√2 = 6√2(3 votes)- Yes, you can take that approach. But, your work is incomplete. When you simplify a square root, you need to ensure you have removed all perfect squares. With 3√8, you still have a perfect square inside the radical.

3√8 = 3√(4*2) = 3√4 * √2 = 3*2√2 = 6√2

Hope this helps.(12 votes)

- how do you do long division(0 votes)
- let me show you an example: 129/3
`43 three "goes in" 43 times`

*______*

3|129

12 3 goes into 12 four times

-12 minus 3*4 (in between 12 and 0, and 3,0 there is a line)

09 remainder of 0. bring down the 9

3(17 votes)

- What's the most efficient way to finding all perfect squares?(4 votes)
*edit*

x x^2 x^3 x^4.......

1 1 1 1

2 4 8 16

3 9 27 81

4 16 64 256

5 25 125 625

6 36 216 1296

7 49 343 2401

8 64 512 4096

9 81 729 6561

10 100 1000 10000

11 121 1331 14641

12 144 1728 20736

.

.

.

I would advise keeping a little chart like this nearby in the beginning to get used to perfect squares....

after time things will start standing out if they seem like they are perfect squares....(8 votes)