Squares, cubes, square roots, and cube roots of algebraic terms

Expand the power and group the terms

We will expand the power and try to group the bases into two equal groups.

We must write the constant coefficient as the product of its prime factors.

\[\begin{align} & \sqrt{9y^{10}} \\ = &\ \sqrt{3 \times 3 \times y \times y \times y \times y \times y \times y \times y \times y \times y \times y} \\ = &\ \sqrt{(3 \times y \times y \times y \times y \times y) \times (3 \times y \times y \times y \times y \times y)} \\ = &\ \sqrt{\left( 3y^{5} \right) \times \left( 3y^{5} \right)} \\ = &\ \sqrt{\left( 3y^{5} \right)^{2}} \\ = &\ 3y^{5} \end{align}\]

Expand the power and group the bases

Expand the power, then group the bases into three equal groups.

We will first expand the power. Then, we will try to group the bases into three equal groups.

\[\begin{align} & \sqrt[3]{t^{6}} \\ = &\ \sqrt[3]{t \times t \times t \times t \times t \times t} \\ = &\ \sqrt[3]{(t \times t) \times (t \times t) \times (t \times t)} \\ = &\ \sqrt[3]{t^{2} \times t^{2} \times t^{2}} \\ = &\ t^{2} \end{align}\]

Check that your answer makes sense. If we multiply our answer by itself three times, we should get what we started with inside the cube root. We have \(t^{2} \times t^{2} \times t^{2} = t^{6}\) so our answer makes sense!

Group the bases into three equal groups.

\[\begin{align} & \sqrt[3]{\frac{125h^{9}}{8}} \\ &= \sqrt[3]{\frac{5h^{3}}{2} \times \frac{5h^{3}}{2} \times \frac{5h^{3}}{2}} \end{align}\]

Give the cube root of the expression.

\[\begin{align} &= \sqrt[3]{\left( \frac{5h^{3}}{2} \right)^{3}} \\ &= \frac{5h^{3}}{2} \end{align}\]

Simplify the expression within the root first.

\[\begin{align} & \sqrt[3]{3t^{2} \times 9t^{4}} \\ &=\ \sqrt[3]{27t^{6}} \end{align}\]

Expand the power and try to group the bases into three equal groups.

We must write the constant coefficient as the product of its prime factors.

\[\begin{align} & \sqrt[3]{3t^{2} \times 9t^{4}} \\ &= \sqrt[3]{27t^{6}} \\ &= \sqrt[3]{3 \times 3 \times 3 \times t \times t \times t \times t \times t \times t} \\ &= \sqrt[3]{(3 \times t \times t) \times (3 \times t \times t) \times (3 \times t \times t)} \\ &= \sqrt[3]{\left( 3t^{2} \right) \times \left( 3t^{2} \right) \times \left( 3t^{2} \right)} \\ &= 3t^{2} \end{align}\]

Add the terms within the cube root.

The terms within the root are like terms, so we will first add them together.

\[\begin{align} & \sqrt[3]{8t^{6} + 19t^{6}} \\ &= \sqrt[3]{27t^{6}} \end{align}\]

Expand the power and try to group the bases into three equal groups.

\[\begin{align} & \sqrt[3]{8t^{6} + 19t^{6}} \\ &= \sqrt[3]{27t^{6}} \\ &= \sqrt[3]{3 \times 3 \times 3 \times t \times t \times t \times t \times t \times t} \\ &= \sqrt[3]{(3 \times t \times t) \times (3 \times t \times t) \times (3 \times t \times t)} \\ &= \sqrt[3]{3t^{2} \times 3t^{2} \times 3t^{2}} \\ &= 3t^{2} \end{align}\]

First divide the powers within the root.

We can simplify the term within the root by dividing the powers of the same base.

\[\begin{align} & \sqrt{\frac{t^{7}}{t}} \\ = & \sqrt{t^{6}} \end{align}\]

Expand the simplified power and try to group the bases into two equal groups.

\[\begin{align} &= \sqrt{t^{6}} \\ &= \sqrt{t \times t \times t \times t \times t \times t} \\ &= \sqrt{\left( t^{3} \right) \times \left( t^{3} \right)} \\ &= t^{3} \end{align}\]

Evaluate.

Use the simplified expression from Step 2.

In Step 2 we determined that \(\sqrt{\frac{t^{7}}{t}}\) is equal to \(t^{3}\). Therefore, we can substitute \(t = 4\) into the simplified expression:

\[\begin{align} \sqrt{\frac{t^{7}}{t}} &= t^{3} \\ &= (4)^{3} \\ &= 64 \end{align}\]

You could also substitute \(t = 4\) into the original expression. Your answer would be the same, but your calculations would be longer.