Difference between revisions of "2011 USAJMO Problems/Problem 1"

Latest revision as of 20:49, 1 October 2021

Problem

Find, with proof, all positive integers $n$ for which $2^n + 12^n + 2011^n$ is a perfect square.

Solution

The answer is $n=1$ , which is easily verified to be a valid integer $n$ . Notice that $2^n+12^n+2011^n\equiv 2^n+7^n \pmod{12}.$ Then for $n\geq 2$ , we have $2^n+7^n\equiv 3,5 \pmod{12}$ depending on the parity of $n$ . But perfect squares can only be $0,1,4,9\pmod{12}$ , contradiction. Therefore, we are done. $\blacksquare$

Solution 1

Let $2^n + 12^n + 2011^n = x^2$ . Then $(-1)^n + 1 \equiv x^2 \pmod {3}$ . Since all perfect squares are congruent to 0 or 1 modulo 3, this means that n must be odd. Proof by Contradiction: We wish to show that the only value of $n$ that satisfies is $n = 1$ . Assume that $n \ge 2$ . Then consider the equation $2^n + 12^n = x^2 - 2011^n$ . From modulo 2, we easily know x is odd. Let $x = 2a + 1$ , where a is an integer. $2^n + 12^n = 4a^2 + 4a + 1 - 2011^n$ . Dividing by 4, $2^{n-2} + 3^n \cdot 4^{n-1} = a^2 + a + \dfrac {1}{4} (1 - 2011^n)$ . Since $n \ge 2$ , $n-2 \ge 0$ , so $2^{n-2}$ similarly, the entire LHS is an integer, and so are $a^2$ and $a$ . Thus, $\dfrac {1}{4} (1 - 2011^n)$ must be an integer. Let $\dfrac {1}{4} (1 - 2011^n) = k$ . Then we have $1- 2011^n = 4k$ . $1- 2011^n \equiv 0 \pmod {4}$ . $(-1)^n \equiv 1 \pmod {4}$ . Thus, n is even. However, it has already been shown that $n$ must be odd. This is a contradiction. Therefore, $n$ is not greater than or equal to 2, and must hence be less than 2. The only positive integer less than 2 is 1.

Solution 2

If $n = 1$ , then $2^n + 12^n + 2011^n = 2025 = 45^2$ , a perfect square.

If $n > 1$ is odd, then $2^n + 12^n + 2011^n \equiv 0 + 0 + (-1)^n \equiv 3 \pmod{4}$ .

Since all perfect squares are congruent to $0,1 \pmod{4}$ , we have that $2^n+12^n+2011^n$ is not a perfect square for odd $n > 1$ .

If $n = 2k$ is even, then $(2011^k)^2 < 2^{2k}+12^{2k}+2011^{2k}$ $= 4^k + 144^k + 2011^{2k} <$ $2011^k + 2011^k + 2011^{2k} < (2011^k+1)^2$ .

Since $(2011^k)^2 < 2^n+12^n+2011^n < (2011^k+1)^2$ , we have that $2^n+12^n+2011^n$ is not a perfect square for even $n$ .

Thus, $n = 1$ is the only positive integer for which $2^n + 12^n + 2011^n$ is a perfect square.

Solution 3

Looking at residues mod 3, we see that $n$ must be odd, since even values of $n$ leads to $2^n + 12^n + 2011^n = 2 \pmod{3}$ . Also as shown in solution 2, for $n>1$ , $n$ must be even. Hence, for $n>1$ , $n$ can neither be odd nor even. The only possible solution is then $n=1$ , which indeed works.

Solution 4

Take the whole expression mod 12. Note that the perfect squares can only be of the form 0, 1, 4 or 9 (mod 12). Note that since the problem is asking for positive integers, $12^n$ is always divisible by 12, so this will be disregarded in this process. If $n$ is even, then $2^n \equiv 4 \pmod{12}$ and $2011^n \equiv 7^n \equiv 1 \pmod {12}$ . Therefore, the sum in the problem is congruent to $5 \pmod {12}$ , which cannot be a perfect square. Now we check the case for which $n$ is an odd number greater than 1. Then $2^n \equiv 8 \pmod{12}$ and $2011^n \equiv 7^n \equiv 7 \pmod {12}$ . Therefore, this sum would be congruent to $3 \pmod {12}$ , which cannot be a perfect square. The only case we have not checked is $n=1$ . If $n=1$ , then the sum in the problem is equal to $2+12+2011=2025=45^2$ . Therefore the only possible value of $n$ such that $2^n+12^n+2011^n$ is a perfect square is $n=1$ .

Solution 5

We will first take the expression modulo $3$ . We get $2^n+12^n+2011^n \equiv -1^n+1^n \pmod 3$ .

Lemma 1: All perfect squares are equal to $0$ or $1$ modulo $3$ . We can prove this by testing the residues modulo $3$ . We have $0^2 \equiv 0 \pmod 3$ , $1^2 \equiv 1 \pmod 3$ , and $2^2 \equiv 1 \pmod 3$ , so the lemma is true.

We know that if $n$ is odd, $-1^n+1^n \equiv 0 \pmod 3$ , which satisfies the lemma's conditions. However, if $n$ is even, we get $2 \pmod 3$ , which does not satisfy the lemma's conditions. So, we can conclude that $n$ is odd.

Now, we take the original expression modulo $4$ . For right now, we will assume that $n>1$ , and test $n=1$ later. For $n>1$ , $2^n \equiv 0 \pmod 4$ , so $2^n+12^n+2011^n=-1^n \pmod 4$ .

Lemma 2: All perfect squares are equal to $0$ or $1$ modulo $4$ . We can prove this by testing the residues modulo $4$ . We have $0^2 \equiv 0 \pmod 4$ , $1^2 \equiv 1 \pmod 4$ , $2^2 \equiv 0 \pmod 4$ , and $3^2 \equiv 1 \pmod 4$ , so the lemma is true.

We know that if $n$ is even, $-1^n \equiv 0 \pmod 4$ , which satisfies the lemma's conditions. However, if $n$ is odd, $-1^n \equiv -1 \equiv 3 \pmod 4$ , which does not satisfy the lemma's conditions. Therefore, $n$ must be even.

However, a number cannot be even and odd at the same time, so this is impossible. Now, we only have to test $n=1$ . We know that $2^1+12^1+2011^1=45^2$ , so the only integer is $\boxed{n=1}$ .

The problems on this page are copyrighted by the Mathematical Association of America's American Mathematics Competitions.

@@ Line 1: / Line 1: @@
+==Problem==
 Find, with proof, all positive integers <math>n</math> for which <math>2^n + 12^n + 2011^n</math> is a perfect square.
 ==Solution==
+The answer is <math>n=1</math>, which is easily verified to be a valid integer <math>n</math>.
+Notice that <cmath>2^n+12^n+2011^n\equiv 2^n+7^n \pmod{12}.</cmath> Then for <math>n\geq 2</math>, we have <math>2^n+7^n\equiv 3,5 \pmod{12}</math> depending on the parity of <math>n</math>. But perfect squares can only be <math>0,1,4,9\pmod{12}</math>, contradiction. Therefore, we are done. <math>\blacksquare</math>
-Let <math>2^n + 12^n + 2011^n = x^2</math>
+==Solution 1==
-<math>(-1)^n + 1 \equiv x^2 \pmod {3}</math>.
-Since all perfect squares are congruent to 0 or 1 modulo 3, this means that n must be odd.
+Let <math>2^n + 12^n + 2011^n = x^2</math>.
+Then <math>(-1)^n + 1 \equiv x^2 \pmod {3}</math>.
+Since all perfect squares are congruent to 0 or 1 modulo 3, this means that n must be odd.
 Proof by Contradiction:
-I will show that the only value of <math>n</math> that satisfies is <math>n = 1</math>.
+We wish to show that the only value of <math>n</math> that satisfies is <math>n = 1</math>.
 Assume that <math>n \ge 2</math>.
 Then consider the equation
 <math>2^n + 12^n = x^2 - 2011^n</math>.
-From modulo 2, we easily that x is odd. Let <math>x = 2a + 1</math>, where a is an integer.
+From modulo 2, we easily know x is odd. Let <math>x = 2a + 1</math>, where a is an integer.
 <math>2^n + 12^n = 4a^2 + 4a + 1 - 2011^n</math>.
 Dividing by 4,
-<math>2^{n-2} + 3^n \cdot 4^{n-1} = a^2 + a + \dfrac {1}{4} (1 - 2011^n})</math>.
+<math>2^{n-2} + 3^n \cdot 4^{n-1} = a^2 + a + \dfrac {1}{4} (1 - 2011^n)</math>.
-Since <math>n \ge 2</math>, <math>n-2 \ge 0</math>, so <math>2^{n-2}</math> similarly, the entire LHS is an integer, and so are <math>a^2</math> and <math>a</math>. Thus, <math> \dfrac {1}{4} (1 - 2011^n})</math> must be an integer.
+Since <math>n \ge 2</math>, <math>n-2 \ge 0</math>, so <math>2^{n-2}</math> similarly, the entire LHS is an integer, and so are <math>a^2</math> and <math>a</math>.
-Let <math> \dfrac {1}{4} (1 - 2011^n}) = k</math>. Then we have <math>1- 2011^n = 4k</math>.
+Thus, <math> \dfrac {1}{4} (1 - 2011^n)</math> must be an integer.
-<math>1- 2011^n \equiv 0 \pmod {4}</math>
+Let <math> \dfrac {1}{4} (1 - 2011^n) = k</math>.
-<math>(-1)^n \equiv 1 \pmod {4}</math>.
+Then we have <math>1- 2011^n = 4k</math>.
-Thus, n is even.
+<math>1- 2011^n \equiv 0 \pmod {4}</math>.
-However, I have already shown that <math>n</math> must be odd. This is a contradiction. Therefore, <math>n</math> is not greater than or equal to 2, and must hence be less than 2. The only positive integer less than 2 is 1.
+<math>(-1)^n \equiv 1 \pmod {4}</math>.
--hrithikguy
+Thus, n is even.
+However, it has already been shown that <math>n</math> must be odd.  This is a contradiction.  Therefore, <math>n</math> is not greater than or equal to 2, and must hence be less than 2.  The only positive integer less than 2 is 1.
 ==Solution 2==
@@ Line 40: / Line 45: @@
 ==Solution 3==
 Looking at residues mod 3, we see that <math>n</math> must be odd, since even values of <math>n</math> leads to <math>2^n + 12^n + 2011^n = 2 \pmod{3}</math>.  Also as shown in solution 2, for <math>n>1</math>, <math>n</math> must be even.  Hence, for <math>n>1</math>, <math>n</math> can neither be odd nor even.  The only possible solution is then <math>n=1</math>, which indeed works.
+==Solution 4==
+Take the whole expression mod 12. Note that the perfect squares can only be of the form 0, 1, 4 or 9 (mod 12). Note that since the problem is asking for positive integers, <math>12^n</math> is always divisible by 12, so this will be disregarded in this process. If <math>n</math> is even, then <math>2^n \equiv 4 \pmod{12}</math> and <math>2011^n \equiv 7^n \equiv 1 \pmod {12}</math>. Therefore, the sum in the problem is congruent to <math>5 \pmod {12}</math>, which cannot be a perfect square. Now we check the case for which <math>n</math> is an odd number greater than 1. Then <math>2^n \equiv 8 \pmod{12}</math> and <math>2011^n \equiv 7^n \equiv 7 \pmod {12}</math>. Therefore, this sum would be congruent to <math>3 \pmod {12}</math>, which cannot be a perfect square. The only case we have not checked is <math>n=1</math>. If <math>n=1</math>, then the sum in the problem is equal to <math>2+12+2011=2025=45^2</math>. Therefore the only possible value of <math>n</math> such that <math>2^n+12^n+2011^n</math> is a perfect square is <math>n=1</math>.
+==Solution 5==
+We will first take the expression modulo <math>3</math>. We get <math>2^n+12^n+2011^n \equiv -1^n+1^n \pmod 3</math>.
+Lemma 1: All perfect squares are equal to <math>0</math> or <math>1</math> modulo <math>3</math>.
+We can prove this by testing the residues modulo <math>3</math>. We have <math>0^2 \equiv 0 \pmod 3</math>, <math>1^2 \equiv 1 \pmod 3</math>, and <math>2^2 \equiv 1 \pmod 3</math>, so the lemma is true.
+We know that if <math>n</math> is odd, <math>-1^n+1^n \equiv 0 \pmod 3</math>, which satisfies the lemma's conditions. However, if <math>n</math> is even, we get <math>2 \pmod 3</math>, which does not satisfy the lemma's conditions. So, we can conclude that <math>n</math> is odd.
+Now, we take the original expression modulo <math>4</math>. For right now, we will assume that <math>n>1</math>, and test <math>n=1</math> later. For <math>n>1</math>, <math>2^n \equiv 0 \pmod 4</math>, so <math>2^n+12^n+2011^n=-1^n \pmod 4</math>.
+Lemma 2: All perfect squares are equal to <math>0</math> or <math>1</math> modulo <math>4</math>.
+We can prove this by testing the residues modulo <math>4</math>. We have <math>0^2 \equiv 0 \pmod 4</math>, <math>1^2 \equiv 1 \pmod 4</math>, <math>2^2 \equiv 0 \pmod 4</math>, and <math>3^2 \equiv 1 \pmod 4</math>, so the lemma is true.
+We know that if <math>n</math> is even, <math>-1^n \equiv 0 \pmod 4</math>, which satisfies the lemma's conditions. However, if <math>n</math> is odd, <math>-1^n \equiv -1 \equiv 3 \pmod 4</math>, which does not satisfy the lemma's conditions. Therefore, <math>n</math> must be even.
+However, a number cannot be even and odd at the same time, so this is impossible. Now, we only have to test <math>n=1</math>. We know that <math>2^1+12^1+2011^1=45^2</math>, so the only integer is <math>\boxed{n=1}</math>.
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