Proving the Solution a=4 and n=2 for a^(1/n) = √a; a>0, n>1

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The discussion confirms that the only solution for the equation \( a^{(1/n)} = \sqrt{a} \) with the constraints \( a > 0 \) and \( n > 1 \) is \( a = 4 \) and \( n = 2 \). Participants demonstrated that for natural numbers, the function \( n^{(n/(n-1))} \) yields a unique integer solution when \( n = 2 \). Additionally, the behavior of the function was analyzed through plotting, revealing a decreasing trend that supports the conclusion of a singular solution under the specified conditions.

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\frac{a}{n}=\sqrt[n]{a};a > 0;n>1
How do I prove that a=4, and n=2 is the only solution? I'm pretty sure it is, but I don't know how to prove it.
 
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the only solution or the onl solution with natural numbers??

If is the only solution you could try to plot it to see how they behave
 


a/n=b a^(1/n)=b

b*n = b^n

n=b^(n-1)

b=n ^(1/(n-1))

a= n^(n/(n-1))With this you can see that if n and a has to be natural there is only one sol and if they don't there are infinite ones.
 


You were correct in assuming that I meant integers. I also plotted it. The shape is interesting, it almost appears linear. Thanks for your help, much appreciated.
 


Wouldn't that result in a dependency? How can you say n^(n/(n-1)) has only one integer solution?
 


n^(n/(n-1))=n^(1+1/(n-1))=n+n^(1/(n-1))

for integers values of n

n= integrer

a=n^(1/(n-1))= only integrer for n=2;

dem: function is decreasing , for n=2 , a=2 for n -> inf a=1
 


Oh... that was a dumb question... Thanks. :)
 


Here's why I was asking:
(aside: how do I impose restrictions on the possible values of a and b? Like say that they must not be equal and that they must be integers?)
a^b=b^a
Which implies that b must equal a, by a factor, n, and a must equal b by a power of 1/n. To make it easier, I'll switch the n and 1/n, since the actual value doesn't matter, just the relation. We can also assume a must be a power of b, because otherwise there would be extraneous factors, making it impossible for them to be equal. Thus we have:
\frac{b}{n}=a;a^n=b
Which you can tell is very similar to the question posed, except the original was simplified.
an=a^n
n=a^{n-1}
a=\sqrt[n-1]{n}
 

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