Our last index law looks at powers that are fractions:
We can define $x^{\frac{1}{n}}=\sqrt[n]{x}$x1n=n√x, that is $x^{\frac{1}{n}}$x1n is the $n^{th}$nth root of $x$x. And then it follows from our previous index laws that:
$x^{\frac{m}{n}}$xmn | $=$= | $\left(x^{\frac{1}{n}}\right)^{^m}$(x1n)m |
$=$= | $\left(\sqrt[n]{x}\right)^m$(n√x)m |
Or
$x^{\frac{m}{n}}$xmn | $=$= | $\left(x^m\right)^{\frac{1}{n}}$(xm)1n |
$=$= | $\sqrt[n]{x^m}$n√xm |
So in general, we have:
We can confirm the definition of $x^{\frac{1}{n}}=\sqrt[n]{x}$x1n=n√x is consistent with our previous index laws if we look at:
For $a>0$a>0: | $a^{\frac{1}{2}}\times a^{\frac{1}{2}}$a12×a12 | $=$= | $a^{\frac{1}{2}+\frac{1}{2}}$a12+12 |
$=$= | $a^1$a1 | ||
$=$= | $a$a | ||
Just as: | $\sqrt{a}\times\sqrt{a}$√a×√a | $=$= | $a$a |
Similarly for higher roots:
For $a>0$a>0: | $\left(a^{\frac{1}{n}}\right)^n$(a1n)n | $=$= | $a^{\frac{1}{n}\times n}$a1n×n |
$=$= | $a^1$a1 | ||
$=$= | $a$a | ||
Just as: | $\left(\sqrt{n}\right)^n$(√n)n | $=$= | $a$a |
When evaluating problems with fractional indices, it doesn't matter whether you start with the powers or the roots, although you might find it more efficient to do it one way than the other.
While we can now use index laws with powers that are any real numbers, it is useful to recognise these common fractional powers:
$x^{\frac{1}{2}}=\sqrt{x}$x12=√x
$x^{\frac{1}{3}}=\sqrt[3]{x}$x13=3√x
Evaluate $16^{\frac{3}{2}}$1632.
We can start by taking the root then applying the power:
$16^{\frac{3}{2}}$1632 | $=$= | $\left(\sqrt{16}\right)^3$(√16)3 |
$=$= | $4^3$43 | |
$=$= | $64$64 |
Or we could start by applying the power then taking the root.
$16^{\frac{3}{2}}$1632 | $=$= | $\sqrt{16^3}$√163 |
$=$= | $\sqrt{4096}$√4096 | |
$=$= | $64$64 |
So, we get the same answer both ways. However, taking the root of $16$16 and then cubing $4$4 may be more efficient than dealing with the larger numbers.
Simplify $\sqrt{27\times x^4}\div\sqrt[3]{3^6x^2}$√27×x4÷3√36x2.
Think: Write roots as fractional powers and simplify using our index laws. Notice we have a base of $27$27 and a base of $3$3, we can express the $27$27 as a base of $3$3 and then combine using our index laws.
Do:
$\sqrt{27\times x^4}\div\sqrt[3]{3^6x^2}$√27×x4÷3√36x2 | $=$= | $\left(3^3\times x^4\right)^{\frac{1}{2}}\div\left(3^6x^2\right)^{\frac{1}{3}}$(33×x4)12÷(36x2)13 |
$=$= | $3^{\left(3\times\frac{1}{2}\right)}x^{\left(4\times\frac{1}{2}\right)}\div3^{\left(6\times\frac{1}{3}\right)}x^{\left(2\times\frac{1}{3}\right)}$3(3×12)x(4×12)÷3(6×13)x(2×13) | |
$=$= | $3^{\frac{3}{2}}x^2\div3^2x^{\frac{2}{3}}$332x2÷32x23 | |
$=$= | $3^{\left(\frac{3}{2}-2\right)}x^{\left(2-\frac{2}{3}\right)}$3(32−2)x(2−23) | |
$=$= | $3^{\frac{-1}{2}}x^{\frac{4}{3}}$3−12x43 | |
$=$= | $\frac{x^{\frac{4}{3}}}{\sqrt{3}}$x43√3 |
Remember that when we raise a negative number to an even power, it becomes a positive number. For instance, $\left(-5\right)^2=25$(−5)2=25. This means that $\sqrt{(-5)^2}=\sqrt{25}=5$√(−5)2=√25=5.
If we now consider the algebraic expression $\sqrt{a^2}$√a2, the power of a power rule indicates that this should simplify to $a$a. As you can see above, however, this is not the case if $a$a is a negative number!
So be careful when simplifying even powers and roots of algebraic expressions - make sure to think about whether or not the variable could represent a negative number.
Express as a fraction in simplest form.
$625^{\frac{-3}{4}}$625−34
Express $\sqrt[5]{x^7}$5√x7 in index form.
Fill in the blanks to simplify the given expression.
$\sqrt{m^8}$√m8 | $=$= | $\left(m^8\right)^{\editable{}}$(m8) |
$=$= | $m^{\editable{}\times\frac{1}{2}}$m×12 | |
$=$= | $m^{\editable{}}$m |
Simplify $\left(625u^{16}v^{12}\right)^{\frac{1}{2}}$(625u16v12)12.
Simplify $\frac{2}{\sqrt{m^4}}\div\frac{\sqrt{m^7}}{5}$2√m4÷√m75, giving your answer in surd form with positive indices.
Simplify $\frac{5^x+5^{\frac{x}{2}}-6}{5^{\frac{x}{2}}-2}$5x+5x2−65x2−2, using the substitution $u=5^{\frac{x}{2}}$u=5x2.
Express your final answer in terms of $x$x.