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I'm working on a homework problem that is as follows:

Suppose that $n$ is a positive even integer with $n/2$ odd. Prove that there do not exist positive integers $x$ and $y$ with $x^2 - y^2 = n$.

It looked like a good candidate for proof by contradiction. So I know that I still assume the argument "$n$ is a positive even integer with $n/2$ odd" but will try to show that there exists positive integers $x$ and $y$ with $x^2 - y^2 = n$, and if this reaches a contradiction then I have proven the original conjecture.

So I started with the $n/2$ is odd and rewrote it as $n/2 = 2k+1$, for some $k$ in the integers.

Then I knew that $n = 4k+2$, and then tried so equate that with $x^2 - y^2 = 4k+2$.

EDIT: I then recognized that $x^2 - y^2$ is equivalent to $(x + y)(x - y)$ but that doesn't seem to be very helpful, because if you divide one or the other out you get a term on the RHS in terms of k and x and y.

I'm going to keep playing with it but I don't really have any good strategies going forward. Any help is appreciated!

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    My bad Matt E. slip of the tongue. Thanks greatly for the correction2012-07-30

9 Answers 9

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A more or less mechanical approach is to work modulo $4$. Note that for any integer $k$, $k^2\equiv 0 \pmod{4}$ or $k^2\equiv 1\pmod{4}$.

So, modulo $4$, $x^2-y^2$ can only take on the values $0$, $1$, and $-1$.


More basic, and more useful, is to suppose that $x^2-y^2=n$. Then $(x-y)(x+y)=n$. Note that for any integers $x$ and $y$, the numbers $x-y$ and $x+y$ are both even or both odd. (If we want a proof, their difference $2y$ is even.)

In neither case is $(x-y)(x+y)$ twice an odd integer. You started along these lines. Note that you were one step from the end.

Remark: The reason the second idea is more useful is that when it comes to solving $x^2-y^2=n$, we express $n$ as a product $st$ of integers of the same parity, and solve the system $x-y=s$, $x+y=t$. The solution is $x=\frac{s+t}{2}$, $y=\frac{s-t}{2}$. If $n$ is twice an odd integer, then this process breaks down, because one of $s$ and $t$ will be odd and the other even, so we do not get integers $x$ and $y$.

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    Okay thanks alot!2012-07-29
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HINT

  1. $x^2 - y^2 = (x-y)(x+y)$
  2. If $x-y$ is even, then so is $x+y$
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For every integer $x$, $x^2=0$ or $1\pmod{4}$. Hence, for every integers $x$ and $y$, $x^2-y^2=1$ or $0$ or $-1\pmod{4}$. On the other hand, if $n=2(2k+1)$ for some integer $k$, $n=2\pmod{4}$. Hence, $x^2-y^2=n\pmod{4}$ with $n$ twice an odd integer is impossible.

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You look at $x^2-y^2=(x+y)(x-y)$, and this factoring can be used to complete the proof.

Since $n$ is even, at least one of $(x+y),(x-y)$ must be even, but then since $n/2$ is odd, the other must be odd. That would mean $(x+y)+(x-y)=2x$ is also odd, which contradicts the existence of integer solutions.

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    Added as a generic version of [my specific answer](http://math.stackexchange.com/a/2191187/206402) when $n=2002$2017-03-21
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$\rm\begin{eqnarray}{\bf Hint}\,\ \ \ If\ prime\,\ p\:|\:a\!-\!b\,\ then\,\ p\:|\:ab\:&\Rightarrow&\:\rm p^2\:|\:ab \\ \rm Therefore\ we\ deduce\ that\,\ 2\:|\:x^2\!-\!y^2&\Rightarrow&\:\rm\ \ 4\:|\:x^2\!-\!y^2\ \ for\ \ p=2,\,\ a,b = x\pm y\end{eqnarray}$

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If $x^2-y^2= N$ and $N/2$ is odd this diophantine equation has no solutions. In fact you can rewrite this equation: $(x-y)(x+y)=N$, but $N$ is even and it is divisibile for $2$ then only one factor is even. So solving this equation with this formula: $x=(p+q)/2$ and $y=(p-q)/2$, where $pq=N$ you obtain two rational solutions.

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1 4 9 16 25

3 5 7 9

the difference of every square is an odd number. If N is even, then for it to be the difference of two squares it must be the sum of an even number of consecutive odd numbers.

3+5=8,,,,,,, 5+7=12 ,,,,,,,, 7+9=16

3+5+7+9=24 ,,,,,,,, 5+7+9+11=32 ,,,,,,,, 7+9+11+13=40

The sequence of the sums of these can be written as 4n+4 and 8n+16 respectively which we can then write as 4(n+1) and 4(2n+4) respectively. The sequence of the sums of any even amount of consecutive odd numbers can be written as 4(kn+k^2) with k being half the amount of consecutive odd numbers. So,

4(kn+k^2)=N

If N is even and when divided by 2 gives an odd number, it is not divisble by 4, so either k or n will not be integers, so N cannot be written as the sum of an even number of consecutive odd numbers.

Therefore,

any even number not divisble by 4 cannot be written as the difference of two squares.

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    Hi Leosha you should use [LaTeX](https://math.meta.stackexchange.com/questions/5020/mathjax-basic-tutorial-and-quick-reference) in your answers in this site as it is easier to read.2017-03-19
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Since for any $a^2-b^2=(a+b)(a-b)=d_1 \cdot d_2=N$ We have $\begin{align} \begin{cases} d_1&=a+b \\ d_2&=a-b \end{cases} \ \ \ \implies \ \ \ \begin{cases} a&=\frac{d_1+d_2}{2}\\ b&=\frac{d_1-d_2}{2} \end{cases} \end{align} \ \ \implies \text{the identity}$

$\left(\frac{d_1+d_2}{2}\right)^2-\left(\frac{d_1-d_2}{2}\right)^2=d_1\cdot d_2$

Meaning that $N$ needs to meet the requirement that it can be factored into two divisors of the same parity. This can be done for any odd number, even prime, as $d_1=\text{prime}$ and $d_2=1$. But not necessarily every even. If the power of 2 in the prime factorization of N is greater than 1, then you have enough 2's to distribute to both divisors, $d_1$ and $d_2$. But if the power of 2 in the prime factorization of N is equal to 1 (as it would be if $\frac{n}{2}$ is odd), then that 2 will have to go in one of the divisors leaving the other odd, resulting in an odd sum or difference, resulting in a non-integer.