$\sqrt {-3}$ multiplied by $\sqrt{-3}$ is $-3$. But this can also be written as $\sqrt {-3} \cdot \sqrt{-3} = \sqrt {(-3).(-3)}= \sqrt{9} =3$
So my question is why is this not possible?
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Usama36
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Your problem is that “$\sqrt{}$” is not a well-defined function outside of the positive reals. In fact, it’s not even well definable. If you define $\sqrt{-3}$ to be that number in the upper half-plane whose square is $-3$, then the rule $\sqrt{ab}=\sqrt a\sqrt b$ fails. – Lubin Jan 02 '17 at 16:35
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http://math.stackexchange.com/questions/1096917/can-someone-prove-why-sqrtab-sqrta-sqrtb-is-only-valid-when-a-and-b-ar – Shraddheya Shendre Jan 02 '17 at 16:35
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1Try to read http://math.stackexchange.com/questions/534940/why-sqrt-1-cdot-sqrt-1-1-rather-than-sqrt-1-cdot-sqrt-1-1-pr?rq=1 – Juniven Acapulco Jan 02 '17 at 16:36
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1Asked zillion times here. – Jan 02 '17 at 16:40
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The reason is the notation $\sqrt{\phantom{0}}$ can be used with two different meanings:
- by abuse of language, $\sqrt{-3}$ denotes any complex number with square equal to $-3$. There are two of them.
- the ‘normal’ $\sqrt{9}$ denotes, of the two (real) numbers with square equal to $9$, the positive one.
Bernard
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While teaching complex numbers, my teacher mentioned it as a theorem:
If a and b are positive real numbers, then $\sqrt{-a}\times\sqrt{-b}=-ab$.
Vidyanshu Mishra
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