Difference between revisions of "2005 USAMO Problems/Problem 2"
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\end{align*} </cmath> | \end{align*} </cmath> | ||
Adding these, we have | Adding these, we have | ||
− | <cmath> (x^3+y+1)^2 - 1 + z^9 | + | <cmath> (x^3+y+1)^2 - 1 + z^9 \equiv -6, </cmath> |
or | or | ||
<cmath> (x^3+y+1)^2 \equiv -z^9 - 5 . </cmath> | <cmath> (x^3+y+1)^2 \equiv -z^9 - 5 . </cmath> |
Latest revision as of 09:38, 12 August 2015
Problem
(Răzvan Gelca) Prove that the system has no solutions in integers , , and .
Solutions
Solution 1
It suffices to show that there are no solutions to this system in the integers mod 19. We note that , so . For reference, we construct a table of powers of five: Evidently, the order of 5 is 9. Hence 5 is the square of a multiplicative generator of the nonzero integers mod 19, so this table shows all nonzero squares mod 19, as well.
It follows that , and . Thus we rewrite our system thus: Adding these, we have or By Fermat's Little Theorem, the only possible values of are and 0, so the only possible values of are , and . But none of these are squares mod 19, a contradiction. Therefore the system has no solutions in the integers mod 19. Therefore the solution has no equation in the integers.
Solution 2
Note that the given can be rewritten as
(1) ,
(2) .
We can also see that
.
Now we notice
for some pair of non-negative integers . We also note that
when
when . If or then examining (1) would yield which is a contradiction. If then from (1) we can see that , plugging this into 2 yields
(3) , , .
Noting that 73 is a prime number we see that it must divide at least 1 of the 2 factors on the right hand side of 3. Let us consider both cases.
.
However
Thus we can see that 73 cannot divide the first factor in the right hand side of (3). Let us consider the next case.
.
However
.
It can be seen that 11 and 15 are not perfect cubes from the following.
We can now see that . Furthermore, notice that if
for a pair of positive integers means that
which cannot be true. We now know that
.
Suppose that
which is a contradiction. Now suppose that
.
We now apply the lifting the exponent lemma to examine the power of 3 that divides each side of the equation when to obtain
.
For we can see that
which is a contradiction. Therefore there only possible solution is when
no integer solutions for k.
Plugging this back into (1) and (2) yields
(4) .
In order for (4) to be true we must have 9 dividing at least 1 of the factors on the right hand side of the equation. Let us consider both cases.
.
However,
.
We now consider the second case.
.
However
Therefore there are no solutions to the given system of diophantine equations.
Solution 3
We will show there is no solution to the system modulo 13. Add the two equations and add 1 to obtain By Fermat's Theorem, when is not a multiple of 13. Hence we compute and . Thus The cubes mod 13 are , , and . Writing the first equation as we see that there is no solution in case and for congruent to , correspondingly must be congruent to . Hence Also is a cube, hence must be . It is easy to check that is not obtained by adding one of to one of . Hence the system has no solutions in integers.
Note: This argument shows there is no solution even if is replaced by .
Alternate solutions are always welcome. If you have a different, elegant solution to this problem, please add it to this page.
See also
- <url>Forum/viewtopic.php?p=213009#213009 Discussion on AoPS/MathLinks</url>
2005 USAMO (Problems • Resources) | ||
Preceded by Problem 1 |
Followed by Problem 3 | |
1 • 2 • 3 • 4 • 5 • 6 | ||
All USAMO Problems and Solutions |
The problems on this page are copyrighted by the Mathematical Association of America's American Mathematics Competitions.