Solve Radical Equations
In this section we will solve equations that have the variable in the radicand of a square root. Equations of this type are called radical equations.
Definition: RADICAL EQUATION
An equation in which the variable is in the radicand of a square root is called a radical equation.
As usual, in solving these equations, what we do to one side of an equation we must do to the other side as well. Since squaring a quantity and taking a square root are ‘opposite’ operations, we will square both sides in order to remove the radical sign and solve for the variable inside.
But remember that when we write \(\sqrt{a}\) we mean the principal square root. So \(\sqrt{a} \ge 0\) always. When we solve radical equations by squaring both sides we may get an algebraic solution that would make \(\sqrt{a}\) negative. This algebraic solution would not be a solution to the original radical equation; it is an extraneous solution. We saw extraneous solutions when we solved rational equations, too.
Example \(\PageIndex{2}\)
For the equation \(\sqrt{x+6}=x\):
- Is x=−2 a solution?
- Is x=3 a solution?
- Answer
-
- no
- yes
Example \(\PageIndex{3}\)
For the equation \(\sqrt{−x+2}=x\):
- Is x=−2 a solution?
- Is x=1 a solution?
- Answer
-
- no
- yes
Now we will see how to solve a radical equation. Our strategy is based on the relation between taking a square root and squaring.
For\(a \ge 0\), \((\sqrt{a})^2=a\)
How to Solve Radical Equations
Example \(\PageIndex{5}\)
Solve: \(\sqrt{3x−5}=5\).
- Answer
-
10
Example \(\PageIndex{6}\)
Solve: \(\sqrt{4x+8}=6\).
- Answer
-
7
Definition: SOLVE A RADICAL EQUATION.
- Isolate the radical on one side of the equation.
- Square both sides of the equation.
- Solve the new equation.
- Check the answer.
Example \(\PageIndex{7}\)
Solve: \(\sqrt{5n−4}−9=0\).
- Answer
-
Example \(\PageIndex{8}\)
Solve: \(\sqrt{3m+2}−5=0\).
- Answer
-
\(\frac{23}{3}\)
Example \(\PageIndex{9}\)
Solve: \(\sqrt{10z+1}−2=0\).
- Answer
-
\(\frac{3}{10}\)
Example \(\PageIndex{10}\)
Solve: \(\sqrt{3y+5}+2=5\).
- Answer
-
Example \(\PageIndex{11}\)
Solve: \(\sqrt{3p+3}+3=5\).
- Answer
-
\(\frac{1}{3}\)
Example \(\PageIndex{12}\)
Solve: \(\sqrt{5q+1}+4=6\).
- Answer
-
\(\frac{3}{5}\)
When we use a radical sign, we mean the principal or positive root. If an equation has a square root equal to a negative number, that equation will have no solution.
Example \(\PageIndex{14}\)
Solve: \(\sqrt{2r−3}+5=0\)
- Answer
-
no solution
Example \(\PageIndex{15}\)
Solve: \(\sqrt{7s−3}+2=0\).
- Answer
-
no solution
If one side of the equation is a binomial, we use the binomial squares formula when we square it.
Definition: BINOMIAL SQUARES
\[\begin{array}{cc} {(a+b)^2=a^2+2ab+b^2}&{(a−b)^2=a^2−2ab+b^2}\\ \nonumber \end{array}\]
Don’t forget the middle term!
Example \(\PageIndex{16}\)
Solve: \(\sqrt{p−1}+1=p\).
- Answer
-
Example \(\PageIndex{17}\)
Solve: \(\sqrt{x−2}+2=x\).
- Answer
-
2, 3
Example \(\PageIndex{18}\)
Solve: \(\sqrt{y−5}+5=y\).
- Answer
-
5, 6
Example \(\PageIndex{19}\)
Solve: \(\sqrt{r+4}−r+2=0\).
- Answer
-
|
\(\sqrt{r+4}−r+2=0\) |
Isolate the radical. |
\(\sqrt{r+4}=r−2\) |
Square both sides of the equation. |
\((\sqrt{r+4})^2=(r−2)^2\) |
Solve the new equation. |
\(r+4=r^2−4r+4\) |
It is a quadratic equation, so get zero on one side. |
\(0=r^2−5r\) |
Factor the right side. |
\(0=r(r−5)\) |
Use the zero product property. |
0=r 0=r−5 |
Solve the equation. |
r=0 r=5 |
Check the answer.
|
r=5 |
|
r=0 is an extraneous solution. |
Example \(\PageIndex{20}\)
Solve: \(\sqrt{m+9}−m+3=0\).
- Answer
-
7
Example \(\PageIndex{21}\)
Solve: \(\sqrt{n+1}−n+1=0\)
- Answer
-
3
When there is a coefficient in front of the radical, we must square it, too.
Example \(\PageIndex{22}\)
Solve: \(3\sqrt{3x−5}−8=4\).
- Answer
-
|
\(3\sqrt{3x−5}−8=4\) |
Isolate the radical. |
\(3\sqrt{3x−5}=12\) |
Square both sides of the equation. |
\((3\sqrt{3x−5})^2=(12)^2\) |
Simplify, then solve the new equation. |
9(3x−5)=144 |
Distribute. |
27x−45=144 |
Solve the equation. |
27x=189 |
|
x=7 |
Check the answer.
|
The solution is x=7. |
Example \(\PageIndex{23}\)
Solve: \(\sqrt{24a+2}−16=16\).
- Answer
-
\(\frac{127}{2}\)
Example \(\PageIndex{24}\)
Solve: \(\sqrt{36b+3}−25=50\).
- Answer
-
\(\frac{311}{3}\)
Example \(\PageIndex{25}\)
Solve: \(\sqrt{4z−3}=\sqrt{3z+2}\).
- Answer
-
|
\(\sqrt{4z−3}=\sqrt{3z+2}\) |
The radical terms are isolated |
\(\sqrt{4z−3}=\sqrt{3z+2}\) |
Square both sides of the equation. |
\((\sqrt{4z−3})^2=(\sqrt{3z+2})^2\) |
Simplify, then solve the new equation |
4z−3=3z+2 |
|
z−3=2 |
|
z=5 |
|
x=7 |
Check the answer.
We leave it to you to show that 5 checks!
|
The solution is z=5. |
Example \(\PageIndex{26}\)
Solve: \(\sqrt{2x−5}=\sqrt{5x+3}\).
- Answer
-
no solution
Example \(\PageIndex{27}\)
Solve: \(\sqrt{7y+1}=\sqrt{2y−5}\).
- Answer
-
no solution
Sometimes after squaring both sides of an equation, we still have a variable inside a radical. When that happens, we repeat Step 1 and Step 2 of our procedure. We isolate the radical and square both sides of the equation again.
Example \(\PageIndex{28}\)
Solve: \(\sqrt{m}+1=\sqrt{m+9}\).
- Answer
-
|
\(\sqrt{m}+1=\sqrt{m+9}\) |
The radical on the right side is isolated.
Square both sides
|
\((\sqrt{m}+1)^2=(\sqrt{m+9})^2\) |
Simplify—be very careful as you multiply! |
\(m+2\sqrt{m}+1=m+9\) |
There is still a radical in the equation.
So we must repeat the previous steps. Isolate the radical.
|
\(2\sqrt{m}=8\) |
Square both sides. |
\((2\sqrt{m})^2=(8)^2\) |
Simplify, then solve the new equation. |
4m=64 |
|
m=16 |
Check the answer.
We leave it to you to show that m=16 checks!
|
The solution is m=16. |
Example \(\PageIndex{29}\)
Solve: \(\sqrt{x}+3=\sqrt{x+5}\).
- Answer
-
no solution
Example \(\PageIndex{30}\)
Solve: \(\sqrt{m}+5=\sqrt{m+16}\).
- Answer
-
no solution
Example \(\PageIndex{31}\)
Solve: \(\sqrt{q−2}+3=\sqrt{4q+1}\).
- Answer
-
|
\(\sqrt{q−2}+3=\sqrt{4q+1}\) |
The radical on the right side is isolated.
Square both sides
|
\((\sqrt{q−2}+3)^2=(\sqrt{4q+1})^2\) |
Simplify. |
\(q−2+6\sqrt{q−2}+9=4q+1\) |
There is still a radical in the equation.
So we must repeat the previous steps. Isolate the radical.
|
\(6\sqrt{q−2}=3q−6\) |
Square both sides. |
\((6\sqrt{q−2})^2=(3q−6)^2\) |
Simplify, then solve the new equation. |
\(36(q−2)=9q^2−36q+36\) |
Distribute. |
\(36q−72=9q^2−36q+36\) |
It is a quadratic equation, so get zero on one side. |
\(0=9q^2−72q+108\) |
Factor the right side. |
\(0=9(q^2−8q+12)\)
\(0=9(q−6)(q−2)\)
|
Use the zero product property |
\[\begin{array}{ll} {q−6=0}&{q−2=0}\\ {q=6}&{q=2}\\ \nonumber \end{array}\] |
The checks are left to you. (Both solutionsshould work.)
|
The solutions are q=6 and q=2. |
Example \(\PageIndex{32}\)
Solve: \(\sqrt{y−3}+2=\sqrt{4y+2}\).
- Answer
-
no solution
Example \(\PageIndex{33}\)
Solve: \(\sqrt{n−4}+5=\sqrt{3n+3}\).
- Answer
-
no solution
Use Square Roots in Applications
As you progress through your college courses, you’ll encounter formulas that include square roots in many disciplines. We have already used formulas to solve geometry applications.
We will use our Problem Solving Strategy for Geometry Applications, with slight modifications, to give us a plan for solving applications with formulas from any discipline.
- Read the problem and make sure all the words and ideas are understood. When appropriate, draw a figure and label it with the given information.
- Identify what we are looking for.
- Name what we are looking for by choosing a variable to represent it.
- Translate into an equation by writing the appropriate formula or model for the situation. Substitute in the given information.
- Solve the equation using good algebra techniques.
- Check the answer in the problem and make sure it makes sense.
- Answer the question with a complete sentence.
We used the formula A=L·W to find the area of a rectangle with length L and width W. A square is a rectangle in which the length and width are equal. If we let s be the length of a side of a square, the area of the square is \(s^2\).
The formula \(A=s^2\) gives us the area of a square if we know the length of a side. What if we want to find the length of a side for a given area? Then we need to solve the equation for s.
\[\begin{array}{ll} {}&{A=s^2}\\ {\text{Take the square root of both sides.}}&{\sqrt{A}=\sqrt{s^2}}\\ {\text{Simplify.}}&{s=\sqrt{A}}\\ \nonumber \end{array}\]
We can use the formula \(s=\sqrt{A}\) to find the length of a side of a square for a given area.
Definition: AREA OF A SQUARE
We will show an example of this in the next example.
Example \(\PageIndex{35}\)
Katie wants to plant a square lawn in her front yard. She has enough sod to cover an area of 370 square feet. Use the formula \(s=\sqrt{A}\) to find the length of each side of her lawn. Round your answer to the nearest tenth of a foot.
- Answer
-
19.2 feet
Example \(\PageIndex{36}\)
Sergio wants to make a square mosaic as an inlay for a table he is building. He has enough tile to cover an area of 2704 square centimeters. Use the formula \(s=\sqrt{A}\) to find the length of each side of his mosaic. Round your answer to the nearest tenth of a foot.
- Answer
-
52.0 cm
Another application of square roots has to do with gravity.
Definition: FALLING OBJECTS
On Earth, if an object is dropped from a height of hh feet, the time in seconds it will take to reach the ground is found by using the formula,
\(t=\frac{\sqrt{h}}{4}\)
For example, if an object is dropped from a height of 64 feet, we can find the time it takes to reach the ground by substituting h=64 into the formula.
|
|
|
|
Take the square root of 64. |
|
Simplify the fraction. |
|
It would take 2 seconds for an object dropped from a height of 64 feet to reach the ground.
Exercise \(\PageIndex{38}\)
A helicopter dropped a rescue package from a height of 1,296 feet. Use the formula \(t=\frac{\sqrt{h}}{4}\) to find how many seconds it took for the package to reach the ground.
- Answer
-
9 seconds
Example \(\PageIndex{39}\)
A window washer dropped a squeegee from a platform 196 feet above the sidewalk Use the formula \(t=\frac{\sqrt{h}}{4}\) to find how many seconds it took for the squeegee to reach the sidewalk.
- Answer
-
3.5 seconds
Police officers investigating car accidents measure the length of the skid marks on the pavement. Then they use square roots to determine the speed, in miles per hour, a car was going before applying the brakes.
Definition: SKID MARKS AND SPEED OF A CAR
If the length of the skid marks is d feet, then the speed, s, of the car before the brakes were applied can be found by using the formula,
\(s=\sqrt{24d}\)
Example \(\PageIndex{41}\)
An accident investigator measured the skid marks of the car. The length of the skid marks was 76 feet. Use the formula \(s=\sqrt{24d}\) to find the speed of the car before the brakes were applied. Round your answer to the nearest tenth.
- Answer
-
42.7 feet
Example \(\PageIndex{42}\)
The skid marks of a vehicle involved in an accident were 122 feet long. Use the formula \(s=\sqrt{24d}\) to find the speed of the vehicle before the brakes were applied. Round your answer to the nearest tenth.
- Answer
-
54.1 feet