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Guias de estudo > ALGEBRA / TRIG I

Square Roots

Learning Outcomes

  • Define and evaluate square roots
  • Estimate square roots that are not perfect
The most common root is the square root. First, we will define what square roots are and how you find the square root of a number. Then we will apply similar ideas to define and evaluate nth roots. Roots are the inverse of exponents, much like multiplication is the inverse of division. Recall that exponents are defined and written as repeated multiplication. Exponent: 32 {{3}^{2}}45 {{4}^{5}}x3 {{x}^{3}}xn {{x}^{\text{n}}} Name: “Three squared” or “Three to the second power”, “Four to the fifth power”, “x cubed”, “x to the nth power” Repeated Multiplication: 33 3\cdot 3,  44444 4\cdot 4\cdot 4\cdot 4\cdot 4,  xxx x\cdot x\cdot x,  xxx...xn times \underbrace{x\cdot x\cdot x...\cdot x}_{n\text{ times}}. Conversely,  when you are trying to find the square root of a number (say, 2525), you are trying to find a number that can be multiplied by itself to create that original number. In the case of 2525, you find that 55=255\cdot5=25, so 55 must be the square root. Find the square roots of the following numbers:
  1. 3636
  2. 8181
  3. 49-49
  4. 00
 
  1. We want to find a number whose square is 3636. 62=366^2=36 therefore,  the nonnegative square root of 3636 is 66 and the negative square root of 3636 is 6-6
  2. We want to find a number whose square is 8181. 92=819^2=81 therefore,  the nonnegative square root of 8181 is 99 and the negative square root of 8181 is 9-9
  3. We want to find a number whose square is 49-49. When you square a real number, the result is always positive. Stop and think about that for a second. A negative number times itself is positive, and a positive number times itself is positive.  Therefore, 49-49 does not have square roots, there are no real number solutions to this question.
  4. We want to find a number whose square is 00. 02=00^2=0 therefore,  the nonnegative square root of 00 is 00.  We do not assign 00 a sign, so it has only one square root, and that is 00.
The symbol for the square root is called a radical symbol and looks like this:    \sqrt{\,\,\,}. The expression 25 \sqrt{25} is read “the square root of twenty-five” or “radical twenty-five.” The number that is written under the radical symbol is called the radicand. The expression: square root of twenty-five is enclosed in a circle. The circle has an arrow pointing to it labeled: Radical expression. The square root symbol has an arrow pointing to it labeled: Radical. The number twenty-five has an arrow pointing to it labeled: Radicand. The notation that we use to express a square root for any real number, a, is as follows:

Writing a Square Root

The symbol for the square root is called a radical symbol. For a real number, a the square root of a is written as a\sqrt{a} The number that is written under the radical symbol is called the radicand. By definition, the square root symbol, 5\sqrt{\hphantom{5}} always means to find the nonnegative root, called the principal root. a[/latex]isnotdefined,therefore[latex]a[/latex]isdefinedfor[latex]a>0\sqrt{-a}[/latex] is not defined, therefore [latex]\sqrt{a}[/latex] is defined for [latex]a>0
Consider 25 \sqrt{25} again. You may realize that there is another value that, when multiplied by itself, also results in 2525. That number is 5−5.

55=2555=25 \begin{array}{r}5\cdot 5=25\\-5\cdot -5=25\end{array}

By definition, the square root symbol always means to find the positive root called the principal root. So while 555\cdot5 and 55−5\cdot−5 both equal 2525, only 55 is the principal root. You should also know that zero is special because it has only one square root: itself (since 00=00\cdot0=0). Let's do an example similar to the example from above, this time using square root notation.  Note that using the square root notation means that you are only finding the principal root - the nonnegative root.

Example

Simplify the following square roots:
  1. 16\sqrt{16}
  2. 9\sqrt{9}
  3. 9\sqrt{-9}
  4. 52\sqrt{5^2}

Answer:

  1. 16\sqrt{16}.  We are looking for a number whose square is 1616, so 16=4\sqrt{16}=4. We only write the nonnegative root because that is how the root symbol is defined.
  2. 9\sqrt{9}.  We are looking for a number whose square is 99, so 9=3\sqrt{9}=3. We only write the nonnegative root because that is how the root symbol is defined.
  3. 9\sqrt{-9}. We are looking for a number whose square is 9-9.  There are no real numbers whose square is 9-9, so this radical is not a real number.
  4. 52\sqrt{5^2}. We are looking for a number whose square is 525^2.  We already have the number whose square is 525^2, it's 55!

The last problem in the previous example shows us an important relationship between squares and square roots, and we can summarize it as follows:

 The square root of a square

For a nonnegative real number, a, a2=a\sqrt{a^2}=a
The following table shows different radicals and their equivalent written and simplified forms.
Radical Name Simplified Form
36 \sqrt{36} “Square root of thirty-six” “Radical thirty-six” 36=62=6 \sqrt{36}=\sqrt{6^2}=6
100 \sqrt{100} “Square root of one hundred” “Radical one hundred” 100=102=10 \sqrt{100}=\sqrt{10^2}=10
225 \sqrt{225} “Square root of two hundred twenty-five” “Radical two hundred twenty-five” 225=152=15 \sqrt{225}=\sqrt{15^2}=15
In the video that follows, we simplify more square roots using the fact that  a2=a\sqrt{a^2}=a means finding the principal square root. https://youtu.be/B3riJsl7uZM

Try It

[ohm_question]228[/ohm_question]

Finding Square Roots Using Factoring

What if you are working with a number whose square you do not know right away?  We can use factoring and the product rule for square roots to find square roots such as 144\sqrt{144}, or  225\sqrt{225}.

The Product Rule for Square Roots

Given that a and b are nonnegative real numbers, ab=ab\sqrt{a\cdot{b}}=\sqrt{a}\cdot\sqrt{b}
In the examples that follow we will bring together these ideas to simplify square roots of numbers that are not obvious at first glance:
  • square root of a square,
  • the product rule for square roots
  • factoring

Example

Simplify 144 \sqrt{144}

Answer: Determine the prime factors of 144144.

14427222362221822229222233\begin{array}{c}\sqrt{144}\\\\\sqrt{2\cdot 72}\\\\\sqrt{2\cdot 2\cdot 36}\\\\\sqrt{2\cdot 2\cdot 2\cdot 18}\\\\\sqrt{2\cdot 2\cdot 2\cdot 2\cdot 9}\\\\\sqrt{2\cdot 2\cdot 2\cdot 2\cdot 3\cdot 3}\end{array}

Because we are finding a square root, we regroup these factors into squares.

222232\sqrt{2^2\cdot 2^2\cdot3^2}

Now we can use the product rule for square roots and the square root of a square idea to finish finding the square root.  

222232=222232=232=12\begin{array}{c}\sqrt{2^2\cdot 2^2\cdot3^2}\\\\=\sqrt{2^2}\cdot\sqrt{2^2}\cdot\sqrt{3^2}\\\\=2\cdot3\cdot2\\\\=12\end{array}

Answer

144=12 \sqrt{144}=12

 

Example

Simplify 225\sqrt{225}

Answer: First, factor 225225:

225=545=559=5533\begin{array}{c}\sqrt{225}\\\\=\sqrt{5\cdot45}\\\\=\sqrt{5\cdot5\cdot9}\\\\=\sqrt{5\cdot5\cdot3\cdot3}\end{array}

Because we are finding a square root, we regroup these factors into squares. Finish simplifying with the product rule for roots, and the square of a square idea.

5232=5232=53=15\begin{array}{c}\sqrt{5^2\cdot3^2}\\\\=\sqrt{5^2}\cdot\sqrt{3^2}\\\\=5\cdot3=15\end{array}

Answer

225=15\sqrt{225}=15

 
CautionCaution!  The square root of a product rule applies when you have multiplication ONLY under the square root. You cannot apply the rule to sums:

a+ba+b\sqrt{a+b}\ne\sqrt{a}+\sqrt{b}

Prove this to yourself with some real numbers: let a=64a = 64 and b=36b = 36, then use the order of operations to simplify each expression.

64+36=100=1064+36=8+6=141014\begin{array}{c}\sqrt{64+36}=\sqrt{100}=10\\\\\sqrt{64}+\sqrt{36}=8+6=14\\\\10\ne14\end{array}

Let's look at some more examples of expressions with square roots.  Pay particular attention to how number 3 is evaluated.

Example

Find the principal root of each expression.
  1. 100\sqrt{100}
  2. 16\sqrt{16}
  3. 25+144\sqrt{25+144}
  4. 4981\sqrt{49}-\sqrt{81}
  5. 81 -\sqrt{81}
  6. 9\sqrt{-9}

Answer:

  1. 100=10\sqrt{100}=10 because 102=100{10}^{2}=100
  2. 16=4\sqrt{16}=4 because 42=16{4}^{2}=16
  3. Recall that square roots act as grouping symbols in the order of operations, so addition and subtraction must be performed first when they occur under a radical. 25+144=169=13\sqrt{25+144}=\sqrt{169}=13 because 132=169{13}^{2}=169
  4. This problem is similar to the last one, but this time subtraction should occur after evaluating the root. Stop and think about why these two problems are different. 4981=79=2\sqrt{49}-\sqrt{81}=7 - 9=-2 because 72=49{7}^{2}=49 and 92=81{9}^{2}=81

  5. The negative in front means to take the opposite of the value after you simplify the radical. 8199 -\sqrt{81}\\-\sqrt{9\cdot 9}. The square root of 8181 is 99. Then, take the opposite of 99 to get (9)−(9)

  6. We are looking for a number that when it is squared returns 9-9. We can try (3)2(-3)^2, but that will give a positive result, and 323^2 will also give a positive result. This leads to an important fact -  you cannot find the square root of a negative number.

In the following video, we present more examples of how to find a principal square root. https://youtu.be/2cWAkmJoaDQ The last example we showed leads reminds us of an important characteristic of square roots. You can only take the square root of values that are non-negative.

Think About It

Does 25=±5\sqrt{25}=\pm 5? Write your ideas and a sentence to defend them in the box below before you look at the answer. [practice-area rows="1"][/practice-area]

Answer: No. Although both 52{5}^{2} and (5)2{\left(-5\right)}^{2} are 2525, the radical symbol implies only a nonnegative root, the principal square root. The principal square root of 25 is 25=5\sqrt{25}=5.

So far, you have seen examples that are perfect squares. That is, each is a number whose square root is an integer. But many radical expressions are not perfect squares. Some of these radicals can still be simplified by finding perfect square factors. The example below illustrates how to factor the radicand, looking for pairs of factors that can be expressed as a square.

Example

Simplify. 63 \sqrt{63}

Answer: Factor 6363

733 \sqrt{7\cdot 3\cdot3}

Regroup factors into squares

732 \sqrt{7\cdot3^2}

Finish simplifying with the product rule for roots, and the square of a square idea.

732=732=73\sqrt{7\cdot3^2}\\\\=\sqrt{7}\cdot\sqrt{3^2}\\\\=\sqrt{7}\cdot3

Since 7 is prime and we can't write it as a square, it will have to stay under the radical sign. As a matter of convention, we write the constant, 33, in front of the radical.  This helps the reader know that the  33 is not under the radical anymore.

37 3\cdot \sqrt{7}

Answer

63=37 \sqrt{63}=3\sqrt{7}

The final answer 37 3\sqrt{7} may look a bit odd, but it is in simplified form. You can read this as “three radical seven” or “three times the square root of seven.”
Picture of a sidewalk leading to a parking lot. There is a path through the grass to teh right of the sidewalk through the trees that has been made by people walking on the grass. The shortcut to the parking lot is the preferred way. Shortcut This Way
In the next example, we take a bit of a shortcut by making use of the common squares we know, instead of using prime factors. It helps to have the squares of the numbers between 00 and 1010 fresh in your mind to make simplifying radicals faster.
  • 02=00^2=0
  • 22=42^2=4
  • 32=93^2=9
  • 42=164^2=16
  • 52=255^2=25
  • 62=366^2=36
  • 72=497^2=49
  • 82=648^2=64
  • 92=819^2=81
  • 102=10010^2=100

Example

Simplify. 2,000 \sqrt{2,000}

Answer: Factor 2,0002,000 to find perfect squares. 10020=10045 \begin{array}{r}\sqrt{100\cdot 20}\\\\=\sqrt{100\cdot 4\cdot 5}\end{array} 100=102,4=22100=10^2,4=2^2

\begin{array}\sqrt{100\cdot 4\cdot 5}\\\\=\sqrt{10^2\cdot 4^2\cdot 5}\\\\=\sqrt{10^2}\cdot \sqrt{4^2}\cdot \sqrt{5}\\\\=10\cdot 4\cdot \sqrt{5}\end{array}

  Multiply.

205 20\cdot \sqrt{5}

Answer

2,000=205 \sqrt{2,000}=20\sqrt{5}

In this last video, we show examples of simplifying radicals that are not perfect squares. https://youtu.be/oRd7aBCsmfU  

Estimate Roots

An approach to handling roots that are not perfect squares is to approximate them by comparing the values to perfect squares. Suppose you wanted to know the square root of 1717. Let us look at how you might approximate it.

Example

Estimate 17 \sqrt{17}

Answer: Think of two perfect squares that surround 17171717 is in between the perfect squares 1616 and 2525. So, 17 \sqrt{17} must be in between 16 \sqrt{16} and 25 \sqrt{25}. Determine whether 17 \sqrt{17} is closer to 44 or to 55 and make another estimate.

16=4 \sqrt{16}=4 and 25=5 \sqrt{25}=5

Since 1717 is closer to 1616 than 2525, 17 \sqrt{17} is probably about 4.14.1 or 4.24.2. Use trial and error to get a better estimate of 17 \sqrt{17}. Try squaring incrementally greater numbers, beginning with 4.14.1, to find a good approximation for 17 \sqrt{17}.

(4.1)2\left(4.1\right)^{2}

(4.1)2\left(4.1\right)^{2} gives a closer estimate than (4.2)2(4.2)^{2}.

4.14.1=16.814.24.2=17.644.1\cdot4.1=16.81\\4.2\cdot4.2=17.64

Continue to use trial and error to get an even better estimate.

4.124.12=16.97444.134.13=17.05694.12\cdot4.12=16.9744\\4.13\cdot4.13=17.0569

174.12 \sqrt{17}\approx 4.12

This approximation is pretty close. If you kept using this trial and error strategy, then you could continue to find the square root to the thousandths, ten-thousandths, and hundred-thousandths places, but eventually it would become too tedious to do by hand. For this reason, when you need to find a more precise approximation of a square root, you should use a calculator. Most calculators have a square root key () (\sqrt{{}}) that will give you the square root approximation quickly. On a simple 44-function calculator, you would likely key in the number that you want to take the square root of and then press the square root key. Try to find 17 \sqrt{17} using your calculator. Note that you will not be able to get an “exact” answer because 17 \sqrt{17} is an irrational number, a number that cannot be expressed as a fraction, and the decimal never terminates or repeats. To nine decimal positions, 17 \sqrt{17} is approximated as 4.1231056264.123105626. A calculator can save a lot of time and yield a more precise square root when you are dealing with numbers that are not perfect squares. The following video shows another example of how to estimate a square root. https://youtu.be/iNfalyW7olk

Try It

[ohm_question]146633[/ohm_question]

Summary

The square root of a number is the number which, when multiplied by itself, gives the original number. Principal square roots are always positive and the square root of 00 is 00. You can only take the square root of values that are nonnegative. The square root of a perfect square will be an integer. Other square roots can be simplified by identifying factors that are perfect squares and taking their square root.  Square roots that are not perfect can also be estimated by finding the perfect square above and below your number.  Also, using a calculator is useful for finding a more precise approximation of a square root.

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