Irrational Numbers- Definition, Examples, Symbol, Properties
Last Updated : 07 Oct, 2024
Irrational numbers are real numbers that cannot be expressed as fractions. Irrational Numbers can not be expressed in the form of p/q, where p and q are integers and q ≠ 0.
They are non-recurring, non-terminating, and non-repeating decimals. Irrational numbers are real numbers but are different from rational numbers.
Examples of Irrational Numbers: √2, √3, π, e, - √7, etc.
In this article, we will learn about irrational numbers, their properties, examples, identification, and others in detail. We will also discuss numerical examples and worksheet on Irrational Numbers.
What is an Irrational Number?
Irrational Numbers are numbers that can not be expressed as the ratio of two integers. They are a subset of Real Numbers and can be expressed on the number line. And, the decimal expansion of an irrational number is neither terminating nor repeating. The symbol of irrational numbers is Q'.
We can define irrational numbers as real numbers that cannot be expressed as p/q where p and q are integers and q ≠ 0.
Irrational Numbers Examples
- √2, √3, π, e are some examples of irrational numbers.
- √2 = 1.41421356237309504880...
- Pi "π"= The value of π is 3.14159265358979323846264338327950... It is a famous irrational number. People have calculated its value up to quadrillion decimals but still haven't found any pattern yet.
- Euler's number "e" = Euler number is also very popular in mathematics. In this case, also, people tried calculating it up to a lot of decimals but still, no pattern was found. the value of e = 2.7182818284590452353602874713527 (and more ...).
- Golden ratio "ϕ" = This is an irrational number and its application is found in many fields like computer science, design, art, and architecture.
Irrational Number Symbol
We represent the Irrational number with the symbol Q' as it represents the group of rational numbers so Q complement (Q') is used to represent irrational numbers. Also,
Q U Q' = R
Where R is the set of real numbers.
How to Identify an Irrational Number?
We know that irrational numbers are real numbers and they cannot be expressed in the form of p/q, where p and q are integers and q ≠ 0. For example, √ 5 and √ 3, etc. are irrational numbers. On the other hand, rational numbers are those that can be written as p/q, where p and q are integers and q ≠ 0.
We know that rational numbers are expressed as, p/q, where p and q are integers and q ≠ 0. But we can not express the irrational number in a similar way. Irrational numbers are non-terminating and non-recurring decimal numbers. So if in a number the decimal value is never ending and never repeating then it is an irrational number.
Some examples of irrational numbers are:
- 1.112123123412345...
- -13.3221113333222221111111..., etc.
Are Irrational Numbers Real Numbers?
Irrational numbers come under real numbers, i.e. all irrational numbers are real. However irrational numbers are different from rational numbers as they can't be written in the form of fractions. Although, irrational numbers can be expressed in the form of non-terminating and non-recurring fractions. For example, √2, √3, and π are all irrational numbers and can't be written as fractions.
The image below explains the relationship between Irrational numbers and Real Numbers.
Properties of Irrational Numbers
Various properties of irrational numbers are given below:
- Sum of two rational numbers may be rational or may be irrational.
- Sum of a rational number and an irrational number is an irrational number.
- Product of an irrational number with a non-zero rational number is an irrational number.
- Product of two irrational numbers may be rational or may be irrational.
- LCM of two irrational numbers may or may not exist.
- Set of irrational numbers is not closed under the multiplication process, but a set of rational numbers is closed.
Read More: Properties of Real Numbers
Operation on Irrational Numbers
Product of Two Irrational Numbers
Product of two rational numbers may be either rational or irrational. For example:
- π × π = π2 is irrational
- √2 × √2 = 2 is rational
So Product of two Irrational Numbers can result in a Rational or Irrational Number accordingly.
Product of Irrational Number and Non-zero Rational Number
The product of any irrational number with any non-zero rational number is an irrational number.
For example, 3 × √2 is an irrational number as it can not be represented as p/q.
Sum of Irrational Numbers
The sum of irrational numbers is sometimes rational sometimes irrational.
- 3√2 + 4√3 is irrational.
- (3√2 + 6) + (- 3√2) = 6, is rational.
Is Pi an Irrational Number?
Yes, Pi (π) is an irrational number because it is neither terminating decimals nor repeating decimals. We will learn more about Pi (π) as:
Let's take a circle, measure its circumference, and divide it by its diameter. It will always be a constant if measured accurately.
This constant ratio is denoted by the Greek symbol π (read as pi). That is:
Circumference/diameter = π
This decimal expansion goes on forever
Note: We often take 22/7 as the value of Pi, but it is an approximation.
Now one might think, how is Pi irrational? One can measure the circumference, One can measure the diameter, and then take their ratio. So it must be rational as we define π as:
π = Circumference/Diameter
And if we define any number as that ratio of two numbers then it is a rational number. But while defining the ratio of π, we take approximation and the value of π is never exactly equal to the ratio of Circumference and Diameter.
For more: Is pi a rational or irrational number?
Is √2 an Irrational Number?
Yes, √2 is an irrational number because it is neither terminating decimals nor repeating decimals. But we can graphically represent the value of √2 as the diagonal of the square with sides one unit as shown in the image below:
Read More about Square Root 2.
Irrational Number on Number Line
An irrational number on a number line is represented as a point that cannot be expressed as a simple fraction or ratio of integers. Unlike rational numbers, which can be depicted as points at specific positions on the number line, irrational numbers cannot be precisely pinpointed due to their non-repeating and non-terminating decimal expansions.
For example, √2 is an irrational number. When plotted on a number line, its approximate position can be determined, but its exact location cannot be identified. This is because √2 is a never-ending, non-repeating decimal. Its decimal representation goes on indefinitely without settling into a repeating pattern.
Similarly, other well-known irrational numbers such as π (pi) and e (Euler's number) cannot be accurately represented by any finite decimal or fraction. They extend infinitely in decimal form without repeating.
List of Irrational Numbers
There are various irrational numbers that are widely used in mathematics. Some of the most commonly used irrational numbers are discussed in the table below:
| Irrational Number | Symbol | Approximate Value |
|---|
| Pi | π | 3.14159265358979… |
| Euler’s Number | e | 2.71828182845904… |
| Golden Ratio | φ | 1.61803398874989…. |
Irrational Number Theorem
The irrational number theorem is:
Theorem: If p is a prime number and p divides a2, then p also divides a.
Proof:
Using the Fundamental Theorem of Arithmetic
We can say that,
a = p1 × p2 × p3……….. × pn …..(i)
where,
p1, p2, p3, ……, pn are prime factors of a.
Squaring both sides of equation (ii)
a2 = (p1 × p2 × p3……….. × pn)2
a2 = (p1)2 × (p2)2 × (p3)2…….. × (pn)2
According to the Fundamental Theorem of Arithmetic. Every natural number has a unique prime factor.
Prime factors of a2 are p1, p2, p3……….., pn. Also, the prime factors of a are, p1, p2, p3……….., pn
Thus, if a2 is divisible by p, then p also divides a.
How to Find Irrational Numbers?
An irrational Number between two prime numbers say a and b is given by √ab.
Irrational numbers between any two numbers are also found using the concept of perfect squares. We know that:
As the perfect squares of the number between them do not exist. So the numbers between them are irrational numbers, i.e. √(2), and √(3) are irrational numbers. Similarly the numbers
So the numbers between them, √(5), √(6), √(7), and √(8) are irrational numbers.
Also, the cube root of the non-perfect cube is an irrational number.
So we can say that the root of prime numbers is irrational numbers. √P is an irrational number where P is the prime number.
This can be proved using the contradiction method is:
Statement: Square root of the prime number is an irrational number.
Proof:
Let us assume that, √u is a rational number.
By the definition of rational numbers
√u =p/q …….(i)
Where p and q have no common factor other than 1 and q ≠ 0
Squaring both sides of equation (1), we have
u = p2/q2
p2 = uq 2 ………. (ii)
Now we can say that if u is a prime factor of p2, then u is a prime factor of p.
Thus,
p = u × c, where c is any integer.
from eq (ii)
(uc)2 = uq2
q2 = uc2...(iii)
From eq(iii) we can say that if u is a prime factor of q2, then u is a prime factor of q.
But initially we have assumes that p and q have no common factors. But from the above proof, we say that p and q have a common factor u, which implies that our initial assumption is wrong. That is √u is not a rational number. Thus, √u is an irrational number.
Also Read: Differences between rational and irrational numbers
Important Points on Irrational Numbers
Non terminating, non recurring decimals are called irrational numbers.
- There are infinite rational numbers between two irrational numbers.
- There are infinite irrational numbers between two rational numbers.
- Irrational numbers can not be represented in form of p/q.
Sample Questions on Irrational Numbers
Question 1: Find Rational Numbers or Irrational Numbers among the following.
2, 3, √3, √2, 1.33333..., 1.1121231234...
Solution:
- Rational Numbers: 2, 3, 1.3333.... are rational numbers
- Irrational Numbers: √3, √2, 1.1121231234... are irrational numbers
Question 2: Find the sum of the following irrational numbers.
a) √2, √2 b) √2, √3
Solution:
a) √2 + √2 = 2√ 2 (they are added as two like variables)
b) √2 + √3 = √2 + √3 (they can't be added as unlike variables)
Question 3: Find the product of the following rational numbers.
a) √2, √2 b) √2, √3
Solution:
a) √2 × √2 = 2
b) √2 × √3 = √6
Irrational Numbers Worksheet
You can download this worksheet from below with answers:
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