Square root of two: Difference between revisions

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(→‎Proof of Irrationality: Inserting exponent for k^2 in two places to correct the equations; adding words to clarify proof by contradiction)
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The [[square root]] of two, denoted <math>\sqrt{2}</math>, is the positive number whose square equals 2. It is approximately 1.4142135623730950488016887242097. It provides a typical example of an [[irrational number]].
The [[square root]] of two, denoted <math>\sqrt{2}</math>, is the positive number whose square equals 2. It is approximately 1.4142135623730950488016887242097. It provides a typical example of an [[irrational number]].


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== Proof of Irrationality ==
== Proof of Irrationality ==
There exists a simple proof by contradiction showing that <math>\sqrt{2}</math> is irrational:
There exists a simple proof by contradiction showing that <math>\sqrt{2}</math> is irrational. This proof is often attributed to [[Pythagoras]]. It is an example of a [[reductio ad absurdum]] type of proof:


Suppose <math>\sqrt{2}</math> is rational.  Then there must exist two numbers, <math>x, y \in \mathbb{N}</math>, such that <math>\frac{x}{y} = \sqrt{2}</math> and <math>x</math> and <math>y</math> represent the smallest such [[integer|integers]] (i.e., they are [[mutually prime]]).
Suppose <math>\sqrt{2}</math> is rational.  Then there must exist two numbers, <math>x, y \in \mathbb{N}</math>, such that <math>\frac{x}{y} = \sqrt{2}</math> and <math>x</math> and <math>y</math> represent the smallest such [[integer|integers]] (i.e., they are [[mutually prime]]).
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Therefore, <math>\frac{x^2}{y^2} = 2</math> and <math>x^2 = 2 \times y^2</math>,
Therefore, <math>\frac{x^2}{y^2} = 2</math> and <math>x^2 = 2 \times y^2</math>,


Thus, <math>x^2</math> represents an [[even number]]
Thus, <math>x^2</math> represents an [[even number]];  therefore <math>x</math> must also be even. This means that there is an integer <math>k</math> such that <math>x = 2 \times k</math>. Inserting it back into our previous equation, we find that <math>(2 \times k)^2 = 2 \times y^2</math>
 
If we take the integer, <math>k</math>, such that <math>k = 2 \times x</math>, and insert it back into our previous equation, we find that <math>(2 \times k)^2 = 2 \times y^2</math>


Through simplification, we find that <math>4 \times k^2 = 2 \times y^2</math>, and then that, <math>2 \times k^2 = y^2</math>,
Through simplification, we find that <math>4 \times k^2 = 2 \times y^2</math>, and then that, <math>2 \times k^2 = y^2</math>,


Since <math>k</math> is an integer, <math>y</math> must ''also'' be even. However, if <math>x</math> and <math>y</math> are both even, they share a common [[factor]] of 2, making them ''not'' mutually prime. And that is a contradiction, so the assumption must be false, and <math>\sqrt{2}</math> must not be rational.
Since <math>k</math> is an integer, <math>y^2</math> and therefore also <math>y</math> must ''also'' be even. However, if <math>x</math> and <math>y</math> are both even, they share a common [[factor]] of 2, making them ''not'' mutually prime. And that is a contradiction, so the assumption must be false, and <math>\sqrt{2}</math> must not be rational.[[Category:Suggestion Bot Tag]]
 
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The square root of two, denoted , is the positive number whose square equals 2. It is approximately 1.4142135623730950488016887242097. It provides a typical example of an irrational number.

In Right Triangles

The square root of two plays an important role in right triangles in that a unit right triangle (where both legs are equal to 1), has a hypotenuse of . Thus, .

Proof of Irrationality

There exists a simple proof by contradiction showing that is irrational. This proof is often attributed to Pythagoras. It is an example of a reductio ad absurdum type of proof:

Suppose is rational. Then there must exist two numbers, , such that and and represent the smallest such integers (i.e., they are mutually prime).

Therefore, and ,

Thus, represents an even number; therefore must also be even. This means that there is an integer such that . Inserting it back into our previous equation, we find that

Through simplification, we find that , and then that, ,

Since is an integer, and therefore also must also be even. However, if and are both even, they share a common factor of 2, making them not mutually prime. And that is a contradiction, so the assumption must be false, and must not be rational.