Section 6.1 Square and \(n\)th Root Properties
¶Objectives: PCC Course Content and Outcome Guide
In this section, we learn what expressions like \(\sqrt{25}\) and \(\sqrt[3]{27}\) mean, and some of the properties they have that allow for simplification.
Subsection 6.1.1 Square Roots
Consider the non-negative number \(25\text{.}\) You can ask the question âwhat number multiplies by itself to make \(25\text{?}\)â We use the symbol \(\sqrt{25}\) to represent the answer to this question, whether or not you know the âanswerâ.
A geometric visualization of the same idea is to imagine a square with \(25\) units of area inside it. What would a side length have to be? We use \(\sqrt{25}\) to represent that side length.
Definition 6.1.2. Square Root.
Given a non-negative number \(x\text{,}\) if \(r\cdot r=x\) for some positive number \(r\text{,}\) then \(r\) is called the square root of \(x\text{,}\) and we can write \(\sqrt{x}\) instead of \(r\text{.}\) The \(\sqrt{\phantom{x}}\) symbol is called the radical or the root. We call expressions with the \(\sqrt{\phantom{x}}\) symbol radical expressions. The number inside the radical is called the radicand.
For example, if you are confronted with the expression \(\sqrt{16}\text{,}\) you should think about the equation \(r\cdot r=16\) (or if you prefer, \(r^2=16\)) and ask yourself if you know a positive value for \(r\) that solves that equation. Of course, \(4\) is a non-negative solution. So we an say \(\sqrt{16}=4\text{.}\)
To demonstrate more of the vocabulary, both \(\sqrt{2}\) and \(3\sqrt{2}\) are radical expressions. In both expressions, the number \(2\) is the radicand.
The word âradicalâ means something like âon the fringesâ when used in politics, sports, and other places. It actually has that same meaning in math, when you consider a square with area \(A\) as in Figure 6.1.3.
The one-digit multiplication times table has special numbers along the diagonal. They are known as perfect squares. And for working with square roots, it will be helpful if you can memorize these first few perfect square numbers. For example, the times table tells us that \(7\cdot7=49\text{.}\) Just knowing that fact from memory lets us know that \(\sqrt{49}=7\text{.}\) It's advisable to memorize the following:
\(\sqrt{0}=0\) | \(\sqrt{1}=1\) | \(\sqrt{4}=2\) |
\(\sqrt{9}=3\) | \(\sqrt{16}=4\) | \(\sqrt{25}=5\) |
\(\sqrt{36}=6\) | \(\sqrt{49}=7\) | \(\sqrt{64}=8\) |
\(\sqrt{81}=9\) | \(\sqrt{100}=10\) | \(\sqrt{121}=11\) |
\(\sqrt{144}=12\) | \(\sqrt{225}=15\) | \(\sqrt{256}=16\) |
\(\times\) | \(1\) | \(2\) | \(3\) | \(4\) | \(5\) | \(6\) | \(7\) | \(8\) | \(9\) |
\(1\) | \(1\) | \(\lowlight{2}\) | \(\lowlight{3}\) | \(\lowlight{4}\) | \(\lowlight{5}\) | \(\lowlight{6}\) | \(\lowlight{7}\) | \(\lowlight{8}\) | \(\lowlight{9}\) |
\(2\) | \(\lowlight{2}\) | \(4\) | \(\lowlight{6}\) | \(\lowlight{8}\) | \(\lowlight{10}\) | \(\lowlight{12}\) | \(\lowlight{14}\) | \(\lowlight{16}\) | \(\lowlight{18}\) |
\(3\) | \(\lowlight{3}\) | \(\lowlight{6}\) | \(9\) | \(\lowlight{12}\) | \(\lowlight{15}\) | \(\lowlight{18}\) | \(\lowlight{21}\) | \(\lowlight{24}\) | \(\lowlight{27}\) |
\(4\) | \(\lowlight{4}\) | \(\lowlight{8}\) | \(\lowlight{12}\) | \(16\) | \(\lowlight{20}\) | \(\lowlight{24}\) | \(\lowlight{28}\) | \(\lowlight{32}\) | \(\lowlight{36}\) |
\(5\) | \(\lowlight{5}\) | \(\lowlight{10}\) | \(\lowlight{15}\) | \(\lowlight{20}\) | \(25\) | \(\lowlight{30}\) | \(\lowlight{35}\) | \(\lowlight{40}\) | \(\lowlight{45}\) |
\(6\) | \(\lowlight{6}\) | \(\lowlight{12}\) | \(\lowlight{18}\) | \(\lowlight{24}\) | \(\lowlight{30}\) | \(36\) | \(\lowlight{42}\) | \(\lowlight{48}\) | \(\lowlight{54}\) |
\(7\) | \(\lowlight{7}\) | \(\lowlight{14}\) | \(\lowlight{21}\) | \(\lowlight{28}\) | \(\lowlight{35}\) | \(\lowlight{42}\) | \(49\) | \(\lowlight{56}\) | \(\lowlight{63}\) |
\(8\) | \(\lowlight{8}\) | \(\lowlight{16}\) | \(\lowlight{24}\) | \(\lowlight{32}\) | \(\lowlight{40}\) | \(\lowlight{48}\) | \(\lowlight{56}\) | \(64\) | \(\lowlight{72}\) |
\(9\) | \(\lowlight{9}\) | \(\lowlight{18}\) | \(\lowlight{27}\) | \(\lowlight{36}\) | \(\lowlight{45}\) | \(\lowlight{54}\) | \(\lowlight{63}\) | \(\lowlight{72}\) | \(81\) |
Subsection 6.1.2 Square Root Decimal Values
Most square roots have decimal places that go on forever. Take \(\sqrt{5}\) as an example. The number \(5\) is between two perfect squares, \(4\) and \(9\text{.}\) Therefore, as demonstrated in Figure 6.1.5, \(\sqrt{4}\lt\sqrt{5}\lt\sqrt{9}\text{.}\) In other words,
So \(\sqrt{5}\) has a decimal value somewhere between \(2\) and \(3\text{.}\)
With a calculator, we can see:
Actually the decimal will not terminate, and that is why we used the \(\approx\) symbol instead of an equals sign. To get \(2.236\) we rounded down slightly from the true value of \(\sqrt{5}\text{.}\) With a calculator, we can check that \(2.236^2=4.999696\text{,}\) a little shy of \(5\text{.}\)
When the radicand is a perfect square, its square root is a rational number. If the radicand is not a perfect square, the square root is irrational. (It has a decimal that goes on forever without any pattern that is easy to see.) We want to be able to estimate square roots without using a calculator.
Example 6.1.6.
To estimate \(\sqrt{10}\) without a calculator, we can find the nearest perfect squares that are whole numbers on either side of \(10\text{.}\) Recall that the perfect squares are \(1, 4, 9, 16, 25, 36, 49, 64,\dots\) The perfect square that is just below \(10\) is \(9\) and the perfect square just above \(10\) is \(16\text{.}\)
This tells us that \(\sqrt{10}\) is between \(\sqrt{9}\) and \(\sqrt{16}\text{,}\) or between \(3\) and \(4\text{.}\) We can also say that \(\sqrt{10}\) is much closer to \(3\) than \(4\) because \(10\) is closer to \(9\text{,}\) so we think \(3.1\) or \(3.2\) would be a good estimate.
To check our estimates (\(3.1\) or \(3.2\)) we can square them and see if the result is close to \(10\text{.}\) We find \(3.1^2=9.61\) and \(3.2^2=10.24\text{,}\) so our estimates are pretty good.
Checkpoint 6.1.7.
Subsection 6.1.3 Cube Root and Higher Order Roots
¶The concept behind a square root easily extends to a cube root. What if we have a number in mind, like \(64\text{,}\) and we would like to know what number can be multiplied with itself three times to make \(64\text{?}\)
A geometric visualization of the same idea is to imagine a cube with \(64\) units of area inside it. What would an edge length have to be? We use \(\sqrt[3]{64}\) to represent that edge length.
Definition 6.1.8. \(n\)th Root.
Given a number \(x\text{,}\) if \(\overbrace{r\cdot r\cdot \cdots \cdot r}^{n\text{ times}}=x\) for some number \(r\text{,}\) then \(r\) is called an \(n\)th root of \(x\text{.}\) (Or if you prefer, when \(r^n=x\text{.}\))
When \(n\) is odd, there is always exactly one real number \(n\)th root for any \(x\text{,}\) and we write \(\sqrt[n]{x}\) to mean that one \(n\)th root.
When \(n\) is even and \(x\) is positive, there are two real number \(n\)th roots, one of which is positive and the other of which is negative. We write \(\sqrt[n]{x}\) to mean the positive \(n\)th root.
When \(n\) is even and \(x\) is negative, there aren't any real number \(n\)th roots, and we say that \(\sqrt[n]{x}\) is ânot a real numberâ.
The \(\sqrt[n]{\phantom{x}}\) symbol is called the \(n\)th radical or the \(n\)th root. We call expressions with the \(\sqrt[n]{\phantom{x}}\) symbol radical expressions. The number inside the radical is called the radicand. The index of a radical is the number \(n\) in \(\sqrt[n]{\phantom{x}}\text{.}\)
As noted earlier, when we have \(\sqrt[3]{\phantom{x}}\text{,}\) we can say âcube rootâ instead of â\(3\)rd rootâ. Also, when we have \(\sqrt[2]{\phantom{x}}\text{,}\) we can say âsquare rootâ instead of â\(2\)nd rootâ and we can simply write \(\sqrt{x}\) instead.
For some examples of \(n\)th roots:
\(\sqrt[3]{8}=2\text{,}\) because \(\overbrace{2\cdot2\cdot2}^{\text{3 instances}}=8\text{.}\)
\(\sqrt[4]{81}=3\text{,}\) because \(\overbrace{3\cdot3\cdot3\cdot3}^{\text{4 instances}}=81\text{.}\)
\(\sqrt[5]{-32}=-2\text{,}\) because \(\overbrace{(-2)\cdot(-2)\cdot(-2)\cdot(-2)\cdot(-2)}^{\text{5 instances}}=-32\text{.}\)
As with square roots, in general an \(n\)th root's decimal value is a decimal that goes on forever. For example, \(\sqrt[3]{20}\approx2.714\ldots\text{.}\) For practical applications, we may want to use a calculator to find a decimal approximation to an \(n\)th root. Some calculators will do this for you directly, and some will not.
Maybe your calculator has a button that looks like \(\sqrt[x]{y}\text{.}\) Then you should be able to type something like
3
\(\sqrt[x]{y}\)20
to get \(\sqrt[3]{20}\approx2.714\ldots\text{.}\)Maybe your calculator has a button that looks like \(\sqrt[n]{\phantom{y}}\text{.}\) Then you should be able to type something like
3
\(\sqrt[n]{\phantom{y}}\)20
to get \(\sqrt[3]{20}\approx2.714\ldots\text{.}\)Maybe your calculator allows you to type letters, parentheses, and commas, and you can type
root(3,20)
to get \(\sqrt[3]{20}\approx2.714\ldots\text{.}\)Maybe your calculator allows you to type letters, parentheses, and commas, but the syntax for an \(n\)th root is reversed from the last example, and you can type
root(20,3)
to get \(\sqrt[3]{20}\approx2.714\ldots\text{.}\)If your calculator has none of the above options, then you should be able to type
20^(1/3)
as a way to get \(\sqrt[3]{20}\approx2.714\ldots\text{.}\) This is technically using mathematics we will learn in Section 6.3.
Try using your own calculator to calculate \(\sqrt[3]{20}\) so that you can become familiar with whatever method it uses.
Example 6.1.9.
A pyramid has a square base, and its height is equal to one side length of the square at its base. In this situation, the volume \(V\) of the pyramid, in in3, is given by \(V=\frac{1}{3}s^3\text{,}\) where \(s\) is the pyramid's base side length in in. Archimedes dropped the pyramid in a bathtub, and judging by how high the water level rose, the volume of the pyramid is 243 in3 (a little more than 1 gal). How tall is the pyramid?
The equation tells us that:
We can multiply on both sides by \(3\) and:
This means that \(s\) is \(\sqrt[3]{729}\text{.}\) A calculator tells us that this is \(9\text{.}\) So the pyramid's height is \(9\) inches.
Subsection 6.1.4 Roots of Negative Numbers
Can we find the square root of a negative number, such as \(\sqrt{-64}\text{?}\) How about its cube root, \(\sqrt[3]{-64}\text{?}\)
As noted in Defintion 6.1.8, when the index of an \(n\)th root is odd, there will always be a real number \(n\)th root even when the radicand is negative. For example, \(\sqrt[3]{-64}\) is \(-4\text{,}\) because \((-4)(-4)(-4)=-64\text{.}\)
When the index of an \(n\)th root is even, it is a problem to have a negative radicand. For example, to find \(\sqrt{-64}\text{,}\) you would need to find a value \(r\) so that \(r\cdot r=-64\text{.}\) But whether \(r\) is positive or negative, multiplying it by itself will give a positive result. It could never be \(-64\text{.}\) So there is no way to have a real number square root of a negative number. And the same thing is true for any even index \(n\)th root with a negative radicand, such as \(\sqrt[4]{-64}\text{.}\) An even-indexed root of a negative number is not a real number.
If you are confronted with an expression like \(\sqrt{-25}\) or \(\sqrt[4]{-16}\) (any square root or even-indexed root of a negative number), you can state that the expression âis not realâ or that it is ânot definedâ (as a real number). Don't get carried away though. Expressions like \(\sqrt[3]{-27}\) and \(\sqrt[5]{-1}\) are defined, because the index is odd.
Subsection 6.1.5 Radical Rules and Exponent Rules
In an earlier chapter, we learned some algebra rules for exponents. A summary of these rules is in List 5.6.13. There are a couple of very similar rules for radicals, presented here without motivation. (These rules are easier to explain once we study Section 6.3.)
Knowing these algebra rules helps to make complicated radical expressions look simpler.
Example 6.1.11.
Simplify \(\sqrt{18}\text{.}\) Anything we can do to make the radicand a smaller simpler number is helpful. Note that \(18=9\cdot2\text{,}\) so we can write
This expression \(3\sqrt{2}\) is considered âsimplerâ than \(\sqrt{18}\) because the radicand is so much smaller.
Checkpoint 6.1.12.
Example 6.1.13.
Simplify \(\sqrt[3]{80}\text{.}\) Anything we can do to make the radicand a smaller simpler number is helpful. With lessons learned from the previous examples, maybe there is a way to rewrite \(80\) as the product of two numbers in a helpful way. Since we have a cube root, writing \(80\) as a product of a perfect cube would be helpful. We can write \(80=8\cdot10\text{,}\) where \(8\) is a perfect cube.
This expression \(2\sqrt[3]{10}\) is considered âsimplerâ than \(\sqrt[3]{80}\) because the radicand is so much smaller.
Checkpoint 6.1.14.
When a radical is applied to a fraction, the Root of a Quotient Rule is useful.
Example 6.1.15.
Simplify \(\sqrt{\frac{8}{25}}\text{.}\) According to the Root of a Quotient Rule,
This is as simple as we can make this expression, unless you prefer to write it as \(\frac{2}{5}\sqrt{2}\text{.}\)
Checkpoint 6.1.16.
Subsection 6.1.6 Multiplying Square Root Expressions
We can use the Root of a Product Rule and the Root of a Quotient Rule to multiply and divide square root expressions. We want to simplify each radical first to keep the radicands as small as possible.
Example 6.1.17.
Multiply \(\sqrt{8}\cdot\sqrt{54}\text{.}\)
We will simplify each radical first, and then multiply them together. We do not want to multiply \(8\cdot54\) because we will end up with a larger number that is harder to factor.
It is worth noting that this is considered as simple as we canmake it, because the radicand of \(3\) is so small.
Checkpoint 6.1.18.
Example 6.1.19.
Multiply \(\sqrt{\frac{6}{5}}\cdot\sqrt{\frac{3}{5}}\text{.}\)
First multiply the fractions together under the radical. Then look for further simplifications.
Subsection 6.1.7 Adding and Subtracting Square Root Expressions
We learned the Root of a Product Rule previously and applied this to multiplication of square roots, but we cannot apply this property to the operations of addition or subtraction. Here are two examples to demonstrate why not.
We do not get the same result if we combine radical sums and differences in the same way we can combine radical products and quotiens.
To add and subtract radical expressions, we need to recognize that we can only add and subtract like terms. In this case, we will call them like radicals. Adding like radicals will work just like adding like terms. In the same way that \(x+3x=4x\) combines two like terms, \(\sqrt{5}+3\sqrt{5}=4\sqrt{5}\) combines two like radicals.
Example 6.1.20.
Simplify \(\sqrt{2}+\sqrt{8}\text{.}\)
First, simplify each radical. Simplifying is the best way to understand whether or not we even have two like radicals that could be combined.
Checkpoint 6.1.21.
Example 6.1.22.
Simplify \(\sqrt{2}+\sqrt{27}\text{.}\)
We cannot simplify the expression further because \(\sqrt{2}\) and \(\sqrt{3}\) are not like radicals.
Example 6.1.23.
Simplify \(\sqrt{6}-\sqrt{18}\cdot\sqrt{12}\text{.}\)
In this example, we should multiply the latter two square roots first (after simplifying them) and then see if we have like radicals.
Subsection 6.1.8 Distributing with Square Roots
¶In Section 5.4, we learned how to multiply polynomials like \(2(x+3)\) and \((x+2)(x+3)\text{.}\) All the methods we learned there apply when we multiply square root expressions. We will look at a few examples done with different methods.
Example 6.1.24.
Multiply \(\sqrt{5}\left(\sqrt{3}-\sqrt{2}\right)\text{.}\)
We will use the distributive property to do this problem:
Example 6.1.25.
Multiply \(\left(\sqrt{6}+\sqrt{12}\right)\left(\sqrt{3}-\sqrt{2}\right)\text{.}\)
We will use the FOIL Method to expand the product. This time, there is an opportunity to simplify some of the radicals after multiplying.
Example 6.1.26.
Expand \(\left(\sqrt{3}-\sqrt{2}\right)^2\text{.}\)
We will use the FOIL method to expand this expression:
Example 6.1.27.
Multiply \(\left(\sqrt{5}-\sqrt{7}\right)\left(\sqrt{5}+\sqrt{7}\right)\text{.}\)
We can once again use the FOIL method to expand this expression. (But it is worth noting that this expression is in the special form \((a-b)(a+b)\) and will simplify to \(a^2-b^2\text{.}\))
Reading Questions 6.1.9 Reading Questions
1.
Is there a difference between \(\sqrt[3]{2}\) and \(3\sqrt{2}\text{?}\) Explain.
2.
Choose one of the radical rules from List 6.1.10. Then find its counterpart in the exponent rules from List 5.6.13.
3.
Describe a way you can visualize \(\sqrt{81}\) in a geometric shape. Describe a way you can visualize \(\sqrt[3]{27}\) in a geometric shape.
Exercises 6.1.10 Exercises
Review and Warmup
1.
Which of the following are square numbers? There may be more than one correct answer.
\(117\)
\(54\)
\(100\)
\(64\)
\(49\)
\(3\)
2.
Which of the following are square numbers? There may be more than one correct answer.
\(1\)
\(125\)
\(16\)
\(115\)
\(121\)
\(138\)
3.
Evaluate the following.
\(\displaystyle{ \sqrt{144} }\) =
\(\displaystyle{ \sqrt{121} }\) =
\(\displaystyle{ \sqrt{36} }\) =
4.
Evaluate the following.
\(\displaystyle{ \sqrt{4} }\) =
\(\displaystyle{ \sqrt{64} }\) =
\(\displaystyle{ \sqrt{144} }\) =
5.
Evaluate the following.
\(\displaystyle{ \sqrt{{{\frac{9}{25}}}} }\) =
\(\displaystyle{ \sqrt{{-{\frac{36}{49}}}} }\) =
6.
Evaluate the following.
\(\displaystyle{ \sqrt{{{\frac{16}{121}}}} }\) =
\(\displaystyle{ \sqrt{{-{\frac{81}{100}}}} }\) =
7.
Evaluate the following.
Do not use a calculator.
\(\displaystyle{ \sqrt{36} }\) =
\(\displaystyle{ \sqrt{0.36} }\) =
\(\displaystyle{ \sqrt{3600} }\) =
8.
Evaluate the following.
Do not use a calculator.
\(\displaystyle{ \sqrt{64} }\) =
\(\displaystyle{ \sqrt{0.64} }\) =
\(\displaystyle{ \sqrt{6400} }\) =
9.
Evaluate the following.
Do not use a calculator.
\(\displaystyle{ \sqrt{64} }\) =
\(\displaystyle{ \sqrt{6400} }\) =
\(\displaystyle{ \sqrt{640000} }\) =
10.
Evaluate the following.
Do not use a calculator.
\(\displaystyle{ \sqrt{100} }\) =
\(\displaystyle{ \sqrt{10000} }\) =
\(\displaystyle{ \sqrt{1000000} }\) =
11.
Evaluate the following.
Do not use a calculator.
\(\displaystyle{ \sqrt{121} }\) =
\(\displaystyle{ \sqrt{1.21} }\) =
\(\displaystyle{ \sqrt{0.0121} }\) =
12.
Evaluate the following.
Do not use a calculator.
\(\displaystyle{ \sqrt{144} }\) =
\(\displaystyle{ \sqrt{1.44} }\) =
\(\displaystyle{ \sqrt{0.0144} }\) =
13.
Without using a calculator, estimate the value of \(\sqrt{18}\text{:}\)
3.76
3.24
4.76
4.24
14.
Without using a calculator, estimate the value of \(\sqrt{24}\text{:}\)
4.10
4.90
5.10
5.90
Simplify Radical Expressions
15.
Evaluate the following.
\(\displaystyle{\sqrt{{{\frac{16}{49}}}}={}}\).
16.
Evaluate the following.
\(\displaystyle{\sqrt{{{\frac{25}{36}}}}={}}\).
17.
Evaluate the following.
\(-\sqrt{64}={}\).
18.
Evaluate the following.
\(-\sqrt{81}={}\).
19.
Evaluate the following.
\(\sqrt{-100}=\).
20.
Evaluate the following.
\(\sqrt{-121}=\).
21.
Evaluate the following.
\(\displaystyle{\sqrt{-{{\frac{121}{144}}}}={}}\).
22.
Evaluate the following.
\(\displaystyle{\sqrt{-{{\frac{4}{25}}}}={}}\).
23.
Evaluate the following.
\(\displaystyle{-\sqrt{{{\frac{9}{121}}}}={}}\).
24.
Evaluate the following.
\(\displaystyle{-\sqrt{{{\frac{16}{81}}}}={}}\).
25.
Evaluate the following.
\(\displaystyle{\sqrt{100}-\sqrt{36}=}\)
\(\displaystyle{\sqrt{100-36}=}\)
26.
Evaluate the following.
\(\displaystyle{\sqrt{100}-\sqrt{64}=}\)
\(\displaystyle{\sqrt{100-64}=}\)
27.
Simplify the radical expression or state that it is not a real number
.
\(\displaystyle{ \frac{{\sqrt{125}}}{{\sqrt{5}}} =}\)
28.
Simplify the radical expression or state that it is not a real number
.
\(\displaystyle{ \frac{{\sqrt{75}}}{{\sqrt{3}}} =}\)
29.
Simplify the radical expression or state that it is not a real number
.
\(\displaystyle{ \frac{{\sqrt{6}}}{{\sqrt{216}}} =}\)
30.
Simplify the radical expression or state that it is not a real number
.
\(\displaystyle{ \frac{{\sqrt{4}}}{{\sqrt{144}}} =}\)
31.
Simplify the radical expression or state that it is not a real number
.
\(\displaystyle{ {\sqrt{8}} = }\)
32.
Simplify the radical expression or state that it is not a real number
.
\(\displaystyle{ {\sqrt{147}} = }\)
33.
Simplify the radical expression or state that it is not a real number
.
\(\displaystyle{ {\sqrt{980}} = }\)
34.
Simplify the radical expression or state that it is not a real number
.
\(\displaystyle{ {\sqrt{216}} = }\)
35.
Simplify the radical expression or state that it is not a real number
.
\(\displaystyle{ {\sqrt{231}} = }\)
36.
Simplify the radical expression or state that it is not a real number
.
\(\displaystyle{ {\sqrt{70}} = }\)
Multiplying Square Root Expressions
37.
Simplify the expression.
\(8\sqrt{3} \cdot 3\sqrt{11}=\)
38.
Simplify the expression.
\(8\sqrt{7} \cdot 8\sqrt{2}=\)
39.
Simplify the expression.
\(9\sqrt{7} \cdot 5\sqrt{{25}} =\)
40.
Simplify the expression.
\(2\sqrt{13} \cdot 2\sqrt{{121}} =\)
41.
Simplify the expression.
\(\displaystyle{2\sqrt{5} \cdot 5\sqrt{40}=}\)
42.
Simplify the expression.
\(\displaystyle{3\sqrt{15} \cdot 3\sqrt{30}=}\)
43.
Simplify the expression.
\(\displaystyle{ {\sqrt{2}} \cdot {3\sqrt{32}} = }\)
44.
Simplify the expression.
\(\displaystyle{ {\sqrt{4}} \cdot {4\sqrt{16}} = }\)
45.
Simplify the expression.
\(\displaystyle{ \sqrt{\frac{2}{7}} \cdot \sqrt{\frac{1}{7}} =}\)
46.
Simplify the expression.
\(\displaystyle{ \sqrt{\frac{1}{8}} \cdot \sqrt{\frac{3}{8}} =}\)
47.
Simplify the expression.
\(\displaystyle{ {\sqrt{\frac{30}{19}}} \cdot {\sqrt{\frac{6}{19}}} =}\)
48.
Simplify the expression.
\(\displaystyle{ {\sqrt{\frac{18}{13}}} \cdot {\sqrt{\frac{6}{13}}} =}\)
Adding and Subtracting Square Root Expressions
49.
Simplify the expression.
\(\displaystyle{{10\sqrt{15}} - {11\sqrt{15}} =}\)
50.
Simplify the expression.
\(\displaystyle{{12\sqrt{11}} - {13\sqrt{11}} =}\)
51.
Simplify the expression.
\(\displaystyle{{13\sqrt{11}} - {13\sqrt{11}} + {15\sqrt{11}} =}\)
52.
Simplify the expression.
\(\displaystyle{{14\sqrt{5}} - {20\sqrt{5}} + {11\sqrt{5}} =}\)
53.
Simplify the expression.
\(\displaystyle{{\sqrt{80}} + {\sqrt{45}} =}\)
54.
Simplify the expression.
\(\displaystyle{{\sqrt{45}} + {\sqrt{125}} =}\)
55.
Simplify the expression.
\(\displaystyle{{\sqrt{343}} - {\sqrt{63}} =}\)
56.
Simplify the expression.
\(\displaystyle{{\sqrt{275}} - {\sqrt{539}} =}\)
57.
Simplify the expression.
\(\displaystyle{{\sqrt{28}} + {\sqrt{175}} + {\sqrt{8}} + {\sqrt{18}} =}\)
58.
Simplify the expression.
\(\displaystyle{{\sqrt{32}} + {\sqrt{8}} + {\sqrt{125}} + {\sqrt{20}} =}\)
59.
Simplify the expression.
\(\displaystyle{{\sqrt{98}} - {\sqrt{8}} - {\sqrt{12}} - {\sqrt{27}} =}\)
60.
Simplify the expression.
\(\displaystyle{{\sqrt{75}} - {\sqrt{27}} - {\sqrt{8}} - {\sqrt{50}} =}\)
Distributing with Square Roots
61.
Expand and simplify the expression.
\(\displaystyle{{\sqrt{2}} \left({\sqrt{19}} + {\sqrt{17}}\right) =}\)
62.
Expand and simplify the expression.
\(\displaystyle{{\sqrt{7}} \left({\sqrt{11}} + {\sqrt{5}}\right) =}\)
63.
Expand and simplify the expression.
\(\displaystyle{\left(3 + {\sqrt{11}}\right)\left(7 + {\sqrt{11}}\right) =}\)
64.
Expand and simplify the expression.
\(\displaystyle{\left(9 + {\sqrt{11}}\right)\left(10 + {\sqrt{11}}\right) =}\)
65.
Expand and simplify the expression.
\(\displaystyle{\left(6 - {\sqrt{7}}\right)\left(7 - 3 {\sqrt{7}}\right) =}\)
66.
Expand and simplify the expression.
\(\displaystyle{\left(3 - {\sqrt{7}}\right)\left(4 - 5 {\sqrt{7}}\right) =}\)
67.
Expand and simplify the expression.
\(\displaystyle{ \left(1+\sqrt{6}\right)^2 =}\)
68.
Expand and simplify the expression.
\(\displaystyle{ \left(2+\sqrt{3}\right)^2 =}\)
69.
Expand and simplify the expression.
\(\displaystyle{ \left(\sqrt{2}-3\right)^2 =}\)
70.
Expand and simplify the expression.
\(\displaystyle{ \left(\sqrt{6}-4\right)^2 =}\)
71.
Expand and simplify the expression.
\(\displaystyle{ \left(\sqrt{15} - \sqrt{5}\right)^2 =}\)
72.
Expand and simplify the expression.
\(\displaystyle{ \left(\sqrt{35} + \sqrt{5}\right)^2 =}\)
73.
Expand and simplify the expression.
\(\displaystyle{\left(8 - 5 {\sqrt{7}}\right)^2 =}\)
74.
Expand and simplify the expression.
\(\displaystyle{\left(5 - 3 {\sqrt{7}}\right)^2 =}\)
75.
Expand and simplify the expression.
\(\displaystyle{\left(10 - {\sqrt{13}}\right)\left(10 + {\sqrt{13}}\right) =}\)
76.
Expand and simplify the expression.
\(\displaystyle{\left(7 - {\sqrt{5}}\right)\left(7 + {\sqrt{5}}\right) =}\)
77.
Expand and simplify the expression.
\(\displaystyle{\left({\sqrt{5}} + {\sqrt{6}}\right)\left({\sqrt{5}} - {\sqrt{6}}\right) =}\)
78.
Expand and simplify the expression.
\(\displaystyle{\left({\sqrt{6}} + {\sqrt{13}}\right)\left({\sqrt{6}} - {\sqrt{13}}\right) =}\)
79.
Expand and simplify the expression.
\(\displaystyle{\left({4\sqrt{5}} + {5\sqrt{7}}\right)\left({4\sqrt{5}} - {5\sqrt{7}}\right) =}\)
80.
Expand and simplify the expression.
\(\displaystyle{\left({5\sqrt{6}} + {3\sqrt{11}}\right)\left({5\sqrt{6}} - {3\sqrt{11}}\right) =}\)
Higher Index Roots
81.
Simplify \({\sqrt[3]{125}}\text{.}\)
82.
Simplify \({\sqrt[3]{27}}\text{.}\)
83.
Simplify \({\sqrt[4]{16}}\text{.}\)
84.
Simplify \({\sqrt[4]{81}}\text{.}\)
85.
Simplify \({\sqrt[5]{32}}\text{.}\)
86.
Simplify \({\sqrt[3]{8}}\text{.}\)
87.
Simplify \({\sqrt[5]{-32}}\text{.}\)
88.
Simplify \({\sqrt[4]{-81}}\text{.}\)
89.
Simplify \({\sqrt[4]{-16}}\text{.}\)
90.
Simplify \({\sqrt[4]{-81}}\text{.}\)
91.
Simplify \({\sqrt[3]{-27}}\text{.}\)
92.
Simplify \({\sqrt[6]{-64}}\text{.}\)
93.
Simplify \({\sqrt[3]{16}}\text{.}\)
94.
Simplify \({\sqrt[3]{162}}\text{.}\)
95.
Simplify \({\sqrt[3]{192}}\text{.}\)
96.
Simplify \({\sqrt[3]{54}}\text{.}\)
97.
Simplify \({\sqrt[3]{80}}\text{.}\)
98.
Simplify \({\sqrt[4]{192}}\text{.}\)
99.
Simplify \({\sqrt[3]{\frac{3}{64}}}\text{.}\)
100.
Simplify \({\sqrt[5]{\frac{11}{32}}}\text{.}\)
101.
Simplify \({\sqrt[3]{\frac{189}{125}}}\text{.}\)
102.
Simplify \({\sqrt[3]{\frac{88}{27}}}\text{.}\)
103.
Simplify \({\sqrt[3]{\frac{54}{125}}}\text{.}\)
104.
Simplify \({\sqrt[3]{\frac{56}{27}}}\text{.}\)