Square root symbol or square root sign is denoted by the symbol ‘√’. It is a mathematical symbol used to represent square roots in mathematics. The square root symbol (√) is also called Radical. For example, we write the square root of 4 as √(4). It is read as root 4 or the square root of 4.
Let’s learn about square root, its representation, simplification, and others in this article.
What is Square Root?
A square root is a number that gives the original number when multiplied by the given number itself. The square root is represented by the √ symbol.
Let’s consider the number “A” which is a positive integer, such that √(A×A) = √(A2) = A
The image showing the square root of the first 30 natural numbers is,
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Example: Find the square root of 36.
√(36)= √(6×6) = 6
Square root of 36 is 6
Concept of Square Root
Concept of a square root can be explained using the following steps:
Step 1: Identify the radicand (the number under the radical symbol).
Step 2: Divide the radicand by any perfect square factor until there are no more perfect square factors left.
Step 3: Write the remaining factors under the radical symbol, and simplify if possible.
Square Root Symbol
Square root of any number is represented using the symbol “√” i.e. square root of 1 is represented as √(1), the square root of 25 is represented as √(25) and similarly, the square root of other numbers can easily be represented.
The image showing square roots symbol is added below:
Radicals
Other name given to the square root symbol is radical. Some mathematicians also called it Surds. The number written inside the radical symbol is called the radicand.
Learn more about Radical
Simplifying Square Roots
This involves simplifying a square root by finding perfect square factors of the radicand and writing them outside the radical symbol.
Example: Simplify √50.
√50 = √(25 × 2)
= √(5 × 5 × 2)
= 5√2
Rationalizing Denominator
This involves multiplying the numerator and denominator of a fraction by the conjugate of the denominator to eliminate the radical from the denominator.
Example: Rationalize the denominator of 1/√5.
Multiply the numerator and denominator by √5 to get (1 x √5)/(√5 x √5) = √5/5.
Using Imaginary Numbers
This involves using the imaginary unit “i”, which is defined as the square root of -1, to represent numbers that cannot be expressed as real numbers.
Example: Find the square root of -25.
√(-25) = √(5 × 5 × -1) = 5i
Repeated Subtraction Method
Subtracting the consecutive odd numbers from the given number till the difference is zero and the required square root is the number of times we subtracted the given number.
Example: Square root of 36.
- 36-1 = 35
- 35-3 = 32
- 32-5 = 27
- 27-7 = 20
- 20-9 = 11
- 11-11 = 0
Here the number is subtracted 6 times. Hence the square root of 36 is 6
Perfect Squares from 1 to 100
Perfect squares from 1 to 100 are discussed in the table
| Square Root of Number |
Simplification |
Result |
| √1 |
√(1×1) |
1 |
| √4 |
√(2×2) |
2 |
| √9 |
√(3×3) |
3 |
| √16 |
√(4×4) |
4 |
| √25 |
√(5×5) |
5 |
| √36 |
√(6×6) |
6 |
| √49 |
√(7×7) |
7 |
| √64 |
√(8×8) |
8 |
| √81 |
√(9×9) |
9 |
| √100 |
√(10×10) |
10 |
Square of First 20 Natural Numbers
Square of the first 20 natural numbers is discussed below in the table,
| Number |
Simplification |
Square |
Number |
Simplification |
Square |
| 1 |
(1×1) |
1 |
10 |
(10×10) |
100 |
| 2 |
(2×2) |
4 |
11 |
(11×11) |
121 |
| 3 |
(3×3) |
9 |
12 |
(12×12) |
144 |
| 4 |
(4×4) |
16 |
13 |
(13×13) |
169 |
| 5 |
(5×5) |
25 |
14 |
(14×14) |
196 |
| 6 |
(6×6) |
36 |
15 |
(15×15) |
225 |
| 7 |
(7×7) |
49 |
16 |
(16×16) |
256 |
| 8 |
(8×8) |
64 |
17 |
(17×17) |
289 |
| 9 |
(9×9) |
81 |
18 |
(18×18) |
324 |
| 10 |
(10×10) |
100 |
19 |
(19×19) |
361 |
| 11 |
(11×11) |
121 |
20 |
(20×20) |
400 |
Square Root of First 20 Natural Numbers
Square root of the first 20 natural numbers is discussed below in the table,
| Number |
Square Root |
Number |
Square Root |
| 1 |
1 |
10 |
3.162 |
| 2 |
1.414 |
11 |
3.317 |
| 3 |
1.732 |
12 |
3.464 |
| 4 |
2 |
13 |
3.606 |
| 5 |
2.236 |
14 |
3.742 |
| 6 |
2.449 |
15 |
3.873 |
| 7 |
2.646 |
16 |
4 |
| 8 |
2.828 |
17 |
4.123 |
| 9 |
3 |
18 |
4.243 |
| 10 |
3.162 |
19 |
4.359 |
| 11 |
3.317 |
20 |
4.472 |
Also, Check
Solved Examples on Square Roots
Example 1: Estimate the square root of 72.
Solution:
Perfect squares closest to 72 are 64 and 81.
Square root of 64 is 8, and the square root of 81 is 9.
Therefore, the square root of 72 is estimated to be between 8 and 9.
Example 2: Simplify √27.
Solution:
We can factor 27 as √(9 × 3), and since the square root of 9 is 3, we can simplify it as 3√3.
Example 3: Simplify √75.
Solution:
We can factor 75 as √(25 × 3), and since the square root of 25 is 5, we can simplify it as 5√3.
Example 4: Simplify 4 / (√2 + √3)
Solution:
To rationalize the denominator, we multiply both the numerator and denominator by (√2 – √3).
= 4×(√2 – √3)/(√2 + √3)(√2 – √3)
= 4×(√2 – √3)/(√2x√2 – √3 √3)
= 4×(√2 – √3)/(2-3)
This gives us [4(√2 – √3)] / (-1), which simplifies to -4(√2 – √3)
Example 5: Simplify (3 + √5) / (√5 – 1)
Solution:
To rationalize the denominator, we multiply both the numerator and denominator by (√5 + 1).
= (3 + √5)(√5 + 1) / (√5 – 1)(√5 + 1) (multiplying by the conjugate of the denominator)
= (3√5 + 3 + √5√5 + √5) / (5 – 1) (expanding the numerator and denominator)
= (4√5 + 8) / 4
= 4(2 + √5) / 4 (cancelling numerator and denominator)
= 2+√5
This gives us [(3 + √5)(√5 + 1)] / (5 – 1), which simplifies to 2 + √5
Example 6: Find the square root of -16.
Solution:
Since the square root of -16 is not a real number,
We can represent it as a complex number of the form a + bi. In this case, we have a = 0 and b = 4.
Therefore, the square root of
-16 = √(i2(4)2)
= 4i
Example 7: Find the square root of -3 – 4i.
Solution:
To find the square root of a complex number we can use the formula,
√(a + bi) = ±(√[(a + √(a2 + b2))/2] + i√[(|a – √(a2 + b2)|)/2])
Applying this formula to the complex number -3 – 4i, we have a = -3 and b = -4. Therefore, we can substitute these values into the formula,
√(-3 – 4i) = ±(√[(-3 + √(9 + 16))/2] + i√[(|-3 – √(9 + 16)|)/2])
= ±(√[(-3 + √(25))/2] + i√[(|-3 – √(25)|)/2])
= ±(√[(-3 + 5)/2] + i√[(|-3 – 5|)/2])
= ±(√(2/2) + i√(|-8|/2))
= ±(√(2/2) + i√(8/2))
= ±(√1 + i√4)
= ±(1 + 2i)
Example 8: Simplify 4 / (√2 – √3)
Solution:
To rationalize the denominator, we multiply both the numerator and denominator by (√2 + √3).
= 4 × (√2 + √3)/(√2 – √3)(√2 + √3)
= 4 × (√2 + √3)/(√2x√2 – √3 √3)
= 4 × (√2 + √3)/(2-3)
This gives us [4(√2 + √3)] / (-1), which simplifies to -4(√2 + √3)
FAQs on Square Roots
What is square root of a number give one example?
A square root is a number that gives the original number when multiplied by the given numberitself.
Example: Find square root of 49
√(49) = √(7×7) = 7
Square root of 49 is 7
Give symbol for representing square root and name of that symbol.
Square root can be represented by using the symbol “√” and we can call it a radical symbol
What is difference between a radical and a square root?
A radical is a mathematical symbol that represents a root, while a square root specifically refers to the root of a number that is multiplied by itself.
Explain square root of an imaginary number.
Square root of a negative number is an imaginary number. For example, the square root of -1 is represented as “i”, the imaginary unit.
What is the Square Root of 4?
Square root of 4 is ±2.
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