$p$ is an odd prime, and $a,b,c$ are integers. If $p$ divides $a^{2023}+b^{2023},b^{2024}+c^{2024},c^{2025}+a^{2025}$, prove that $p$ divides $a,b,c$.

Question

$p$ is an odd prime, and $a,b,c$ are integers. If $p$ divides each of $$a^{2023}+b^{2023},\ b^{2024}+c^{2024}, \ c^{2025}+a^{2025}$$prove that $p$ divides $a,b,c$.

This question appeared in INMO 2024 (the contest is over now).

This is how I did it:
$$a^{2023} \equiv -b^{2023} \pmod p$$ $$b^{2024} \equiv -c^{2024} \pmod p$$ $$c^{2025} \equiv -a^{2025} \pmod p$$ Assume, for the sake of contradiction, $p$ does not divide all of them. $\implies$ $p$ does not divide any of them (it can not divide exactly two or one of them).

So, it makes sense to divide and multiply congruences by $a,b,c$.
Multiplying the above three and cancelling terms, we have: $$-bc \equiv a^2 \pmod p$$ Now, we put this in the congruences: $$-b^{2023} \equiv a^{2023} \equiv a(a^{2022}) \equiv -ab^{1011}c^{1011} \pmod p$$ $$\implies ab^{1012} \equiv a^2c^{1011} \pmod p$$ Putting $a^2 \equiv -bc \pmod p$ in the other congruence: $$-c^{2025} \equiv a^{2025} \equiv a(a^{2024}) \equiv a(-bc)^{1012} \equiv ab^{1012}c^{1012} \equiv a^2c^{1011}c^{1012} \pmod p$$ $$\implies c^2 \equiv -a^2 \equiv bc \pmod p$$ $$\implies b \equiv c \pmod p$$ $$b^{2024} \equiv c^{2024} \equiv -b^{2024} \pmod p$$ Since $p$ is odd, this implies $p$ divides $b$, a contradiction.

However, this seems too easy to be true. Is there another way to present the proof that clarifies the correctness and key idea?

Answer 1

Clearer: we have $i,\color{#c00}j,k = 2023,\color{#c00}{2024},2025$ with $\color{#c00}j$ even, $\color{#90f}{i,k}$ odd, so we get a $\rm\color{darkorange}{contradiction}$ by raising the congruences to a common power $\,m = ijk\,$ then taking their product, i.e.

$$\begin{align} [a^i \equiv -b^i]^{jk}\ \Rightarrow\ \color{#0af}{a^m}&\equiv\ \color{#0a0}{b^m}\ \ \ \ \ {\rm by}\ \ \color{#c00}jk\ \ \rm even\\[.2em] [b^j \equiv -c^j]^{ki}\ \Rightarrow\ \color{#0af}{b^m}&\equiv \color{#0a0}{-c^m}\ \ \ {\rm by}\ \ \color{#90f}{ki}\ \ \rm odd\\[.2em] [c^k \equiv -a^k]^{ij}\ \Rightarrow\ \color{#0af}{c^m}&\equiv\ \color{#0a0}{a^m}\ \ \ \ \ {\rm by}\ \ i\color{#c00}j\ \ \rm even_{\phantom{|}} \\[.2em] \hline {\rm multiplying\ rows}\ \Rightarrow\ \color{#0af}{(abc)^m}&\equiv \color{#0a0}{-(abc)^{m^{\phantom|}}} \color{darkorange}{\Rightarrow\!\Leftarrow} \end{align}\qquad\qquad$$

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Remark $ $ This boils down to a multiplicative form of a basic ($p$-adic) nonintegrality test for a sum of fractions, i.e. for $\,x,y,z = a/b,\,b/c,\,c/a\,$ the above proof is equivalent to the first line below. The 2nd line is an additive analog, which is rewritten in fraction language in the 3rd line.

$\begin{align} -1 = x^i = y^j = z^k,\:\!\ 1\:\! = x\:\!\cdot\:\! y\:\!\cdot\:\! z \,\Rightarrow\ &1^m\! = (x\cdot y\cdot z)^m\! =\! (-1)^s\text{ contra $\rm\color{#90f}{odd}$ } s \!=\! \!\color{#90f}{ki}\!+\!\color{#c00}j(k\!+\!i)\\[.4em] 1/2 = ix = jy = kz,\ n=x\!+\!y\!+\!z \, \Rightarrow\ &\!mn = m(x\!+\!y\!+\!z)\! = s/2\:\! \text{ contra odd } s,\ mn\in\Bbb Z\\ {\rm i.e.}\ \ \ x\!+\!y\!+\!z\, =\ \ &\!\! \frac{1}{2i} \!+\! \frac{1}{2\color{#c00}j}\!+\!\frac{1}{2k} \not\in \Bbb Z\,\text{ if exactly $\rm\color{#c00}{one}$ of $\,i,\color{#c00}j,k\,$ is even} \end{align}$

The prior line generalizes from $\,2\,$ to any prime $\,p,\,$ i.e. a sum of fractions is nonintegral if the highest power of $\,p\,$ in any denominator occurs in exactly $\rm\color{#c00}{one}$ denominator, and the above multiplicative form generalizes using this $ $ (replace $\,{-}1\,$ by any element of order $\,p,\,$ e.g. use $\,\zeta_p\,$ (a primitive $\:\!p$'th root of $1).\,$

This basic fact about fractions is ubiquitous in number theory but - curiously - it seems it is not widely taught in elementary courses (witness: this simple proof with that key idea got $> 300$ upvotes). That pedagogical gap will be remedied when one studies advanced number theory, where this method is a trivial prototypical example of local-global methods (valuation theory and $p$-adics). Further, group theory rigorously explains the analogy between the additive and multiplicative forms (see also posts on denominator and order ideals). After mastering these generalizations and abstractions, it is much easier to recognize such reformulations - whether their genesis is nature or a sneaky contest problem composer attempting to obfuscate such basic results to complicate solutions.

Answer 2

Your solution is fine.

As to whether it will fetch full marks, because this is a very simple question for the INMO, they might be strict about the grading. Depending on what you actually wrote, they might get nitpicky with the following phrasing:

1.

$p$ does not divide all of them. $\Rightarrow p$ does not divide any of them (it can not divide exactly two or one of them).

which skipped a minor step.

I would have preferred an explicit $ p \mid a \Rightarrow p \mid b \Rightarrow p \mid c$ (and similar cyclic expressions).

Alternatively, you could have said "Assume $p \not \mid b$, then $ p \not \mid c, p \not \mid a$.

2.

makes sense to divide and multiply congruences

What you mean is that we can divide the congruences and still have them hold true. (We can always multiply.)

By saying "makes sense", I interpret that as your motivation for the approach, and so you have not shown awareness of this fact (which is admittedly obvious and trivial for the INMO).

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An easier argument is, working mod $p$,

$ \begin{array} {l l} a^ { 2023 \times 2024 \times 2025} & \equiv (-b^{2023} ) ^{2024\times 2025} \\ & \equiv b^{2023 \times 2024 \times 2025} \\ & \equiv (b^{2024})^{2023 \times 2025} \\ & \equiv (-c^{2024})^{2023 \times 2025} \\ & \equiv -c^{2023 \times 2024 \times 2025} \\ & \equiv - (c^{2025} ) ^{2023 \times 2024} \\ & \equiv -(-a^{2025})^{2024 \times 2025} \\ &\equiv -a^{2023\times2024\times 2025} \end{array}$

Hence $ a \equiv 0 \pmod{p}$ for an odd prime.
Finally, $ p \mid a \Rightarrow p \mid b \Rightarrow p \mid c$

Note

• Easier in the sense that the next step is motivated, and I didn't have to keep track of powers.
• This also showcases why the important aspect is that two of the exponents are odd and one is even.
• I suspect a similar question has been used before in a competition.

Answer 3

My attempt, Let, $p$ doesn't divide any one of $a, b, c$ then it does not divide all of $a,b,c$ by the conditions of the problem given. Let $p>2$ and $g$ be the primitive root modulo $p$. Then $$a\equiv g^{k_1}\pmod p $$ $$b\equiv g^{k_2}\pmod p$$ $$c\equiv g^{k_3}\pmod p$$ Note that we can choose $k_1,k_2,k_3$ such that, $k_1\geq k_2\geq k_3$ cause of periodicity of modulo $p-1$ or that is to say for classes of the group $(\mathbb{Z}_p^{\times}, \times)$. Then the condition given will imply there exist positive integers, $l_1,l_2,l_3$ such that $$2\times 2023(k_1-k_2)=l_1(p-1)$$ $$2\times 2024(k_2-k_3)=l_2(p-1)$$ $$2\times 2025(k_1-k_3)=l_3(p-1)$$ as, $ord_{p} (g) =p-1=\phi(p)$ Then, $$\frac{l_1}{2023}+\frac{l_2}{2024}=\frac{l_3}{2025}$$, Note that,by rearranging this equation as $\gcd(2025,2024\times 2023)=1$ then $2025$ divides $l_3$, Similarly, $2023$ divides $l_1$ and $2024$ divides $l_2$ Hence, there exist integers $m_1,m_2,m_3$ such that, $$l_1=2023m_1,l_2=2024m_2,l_3=2025m_3$$ $$k_1-k_2=m_1(\frac{p-1}{2})$$ $$k_2-k_3=m_2(\frac{p-1}{2})\cdots (*)$$ $$k_1-k_3=m_3(\frac{p-1}{2})$$ Then by 2nd equation given in the question that is $p|b^{2024} +c^{2024} $ we have $p|g^{2024(k_2-k_3)}+1$ but by $(*)$ we have $p|g^{1012m_2(p-1)}+1$ which is a contradiction as $g$ is a primitive root and also $p>2$ $\blacksquare$

Remark: It doesn't matter what odd prime $p$ we choose we can choose $k_1,k_2,k_3$ such that $$2\times 2023(k_1-k_2)>(p-1)$$ $$2\times 2024(k_2-k_3)>(p-1)$$ $$2\times 2025(k_1-k_3)>(p-1)$$ But, due to the order of an integer modulo $p$ we must have $$2\times 2023(k_1-k_2)$$ $$2\times 2024(k_2-k_3)$$ $$2\times 2025(k_1-k_3)$$ a multiple of $p-1$. Hence the above result is truthful. Infact true for any prime of the form $p=2\times 2023\times 2024 \times 2025 \times s +1$, which exist due to dirichlet's theorem arithmetic progression of primes, but may not necessary for this problem.