On the equation $a^p + 2^\alpha b^p + c^p =0$
Kenneth Ribet
We discuss the equation $a^p + 2^\alpha b^p + c^p =0$ in which $a$, $b$, and $c$ are non-zero relatively prime integers, $p$ is an odd prime number, and $\alpha$ is a positive integer. The technique used to prove Fermat's Last Theorem shows that the equation has no solutions with $\alpha>1$ or $b$ even. When $\alpha=1$ and $b$ is odd, there are the two trivial solutions $(\pm 1, \mp 1, \pm 1)$. In 1952, Déenes conjectured that these are the only ones. Using methods of Darmon, we prove this conjecture for $p\equiv1$ mod 4. We link the case $p\equiv3$ mod 4 to conjectures of Frey and Darmon about elliptic curves over $\Bbb Q$ with isomorphic mod $p$ Galois representations.