How would you proove a^-n = 1/a^n?

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The discussion centers on proving the equation a^-n = 1/a^n, with participants exploring the definition and implications of negative exponents. One contributor attempts a proof using properties of exponents but questions whether it adds any new understanding. The conversation highlights the challenge of defining exponentiation for negative integers and the need to extend definitions beyond positive integers. Participants discuss the relationship between multiplication and exponentiation, suggesting that understanding these concepts can clarify the proof. Ultimately, the dialogue emphasizes the importance of foundational knowledge in mathematics to grasp such equations.
okunyg
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I can't find many proofs of how the equation in the thread title is correct. How would you proove the equation?

I tried to make one, but I don't know if it's worth mentioning. What do you think about my "proof"?

a^-n = a^0-n = (a^0)/(a^n) = 1/a^n
 
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you assume that a^b a^c = a^(b+c).
 
I'm sorry, could you elaborate a little? Do I assume? Do you assume? What does that equation have to do with this?

You might notice that I'm a beginner.


Edit: Oh, I believe I know what you mean: I did not proove anything, I just wrote something obvious that someone else has figured out? Kind of like not thinking on my own?
 
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The problem is this: what does xn mean when n is a negative integer? If you have defined exponentiation in terms of repeated multiplication, then what does it mean to multiply something by itself -3 or 0 times? Once you have defined exponentiation for these (and other) values, there is nothing really to prove.
 
okunyg said:
I'm sorry, could you elaborate a little? Do I assume? Do you assume? What does that equation have to do with this?

You assume that you know what x^2, x^3 means etc. Then you notice that (x^a)^b = x^(ab), and other such rules, that make you realize that it is reasonable to extend thee definition from just the positive whole numbers to all rational numbers via x^{1/n} as the n'th root of x, and x^-n as 1/x^n
 
Because by multiplying both side of the equation by a^m, with m>n, it makes sense.

Doing so on this equation:

a^-n = 1/a^n

leads to

a^(m-n) = a^m/a^n

which makes sense (already) for m>=n .
 
in other words: isomorphism ...
 
What does isomorphism have to do with anything? :confused:
 
well, summing exponents is similar to making products
there is an isomorphism between:

- the set of positive numbers equipped with multiplication
- the set of all numbers equipped with the addition

(sorry for the lose speaking, this is very old for me)
 

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