Math, asked by MOHDADNANQURESHI, 1 year ago

prove root 2+ root 5 is irrational​

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Answered by Anonymous
12

Question :-

Prove that √2 + √5 is irrational.

Solution :-

Let us assume that √2 + √5 is rational.

i.e, √2 + √5 = a/b where 'a' and 'b' are co primes and b ≠ 0

 \tt   \sqrt{2} +  \sqrt{5} =  \dfrac{a}{b}

 \tt  \sqrt{2} =  \dfrac{a}{b} -  \sqrt{5}

Squaring on both sides

 \tt  (\sqrt{2})^{2}  =  (\dfrac{a}{b} -  \sqrt{5})^{2}

 \tt  \sqrt{4}  =  (\dfrac{a}{b})^{2} - 2( \dfrac{a}{b})( \sqrt{5}) +  {( \sqrt{5})}^{2}

[Since (x - y)² = x² - 2xy + y² and above in RHS x = a/b, y = √5 ]

 \tt 2  = \dfrac{a^{2} }{b^{2} } - 2\sqrt{5}. \dfrac{a}{b} + \sqrt{25}

 \tt 2  = \dfrac{a^{2} }{b^{2} } - 2\sqrt{5}. \dfrac{a}{b} + 5

 \tt 2 \sqrt{5}. \dfrac{a}{b}    = \dfrac{a^{2} }{b^{2} }+ 5 - 2

 \tt 2 \sqrt{5}. \dfrac{a}{b}    = \dfrac{a^{2} }{b^{2} }+ 3

Taking LCM in RHS

 \tt 2 \sqrt{5}. \dfrac{a}{b}    = \dfrac{a^{2}  + 3b^{2} }{b^{2} }

 \tt 2 \sqrt{5}    = \dfrac{a^{2}  + 3b^{2} }{b^{2} } \times  \dfrac{b}{a}

 \tt 2 \sqrt{5}    = \dfrac{a^{2}  + 3b^{2} }{b } \times  \dfrac{1}{a}

 \tt 2 \sqrt{5}    = \dfrac{a^{2}  + 3b^{2} }{ab}

 \tt \sqrt{5}    = \dfrac{a^{2}  + 3b^{2} }{2ab}

Since 'a' and 'b' are integers Right Hand Side i.e  \tt \dfrac{ {a}^{2} + 3{b}^{2} }{2ab} is a rational number.

So, Left Hand Side of the equation is a rational number.

But, this contradicts the fact that √5 is irrational.

This contradiction has arised because of our wrong assumption that √2 + √5 is rational.

So we can conclude that √2 + √5 is irrational.

Hence proved.

Answered by Anonymous
10

Question :-

Prove that √2 + √5 is irrational.

Solution :-

Let us assume that √2 + √5 is rational.

i.e, √2 + √5 = a/b where 'a' and 'b' are co primes and b ≠ 0

\tt \sqrt{2} + \sqrt{5} = \dfrac{a}{b}

\tt \sqrt{2} = \dfrac{a}{b} - \sqrt{5}

Squaring on both sides

\tt (\sqrt{2})^{2} = (\dfrac{a}{b} - \sqrt{5})^{2}

\tt \sqrt{4} = (\dfrac{a}{b})^{2} - 2( \dfrac{a}{b})( \sqrt{5}) + {( \sqrt{5})}^{2}

[Since (x - y)² = x² - 2xy + y² and above in RHS x = a/b, y = √5 ]

\tt 2 = \dfrac{a^{2} }{b^{2} } - 2\sqrt{5}. \dfrac{a}{b} + \sqrt{25}

\tt 2 = \dfrac{a^{2} }{b^{2} } - 2\sqrt{5}. \dfrac{a}{b} + 52

\tt 2 \sqrt{5}. \dfrac{a}{b} = \dfrac{a^{2} }{b^{2} }+ 5 - 22

\tt 2 \sqrt{5}. \dfrac{a}{b} = \dfrac{a^{2} }{b^{2} }+ 32

Taking LCM in RHS

\tt 2 \sqrt{5}. \dfrac{a}{b} = \dfrac{a^{2} + 3b^{2} }{b^{2} }2

\tt 2 \sqrt{5} = \dfrac{a^{2} + 3b^{2} }{b^{2} } \times \dfrac{b}{a}2

\tt 2 \sqrt{5} = \dfrac{a^{2} + 3b^{2} }{b } \times \dfrac{1}{a}2

\tt 2 \sqrt{5} = \dfrac{a^{2} + 3b^{2} }{ab}2

\tt \sqrt{5} = \dfrac{a^{2} + 3b^{2} }{2ab}

Since 'a' and 'b' are integers Right Hand Side i.e

\tt \dfrac{ {a}^{2} + 3{b}^{2} }{2ab}

is a rational number.

So, Left Hand Side of the equation is a rational number.

But, this contradicts the fact that √5 is irrational.

This contradiction has arised because of our wrong assumption that √2 + √5 is rational.

So we can conclude that √2 + √5 is irrational.

Hence proved :)

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