Difference between revisions of "2024 USAMO Problems/Problem 1"
Line 10: | Line 10: | ||
Note that if we have a prime number <math>p>n</math> and an integer <math>k>p</math> such that both <math>k</math> and <math>k+1</math> are factors of <math>n!</math>, then the condition cannot be satisfied. | Note that if we have a prime number <math>p>n</math> and an integer <math>k>p</math> such that both <math>k</math> and <math>k+1</math> are factors of <math>n!</math>, then the condition cannot be satisfied. | ||
− | If <math>n\geq7</math> is odd, then <math>(2)(\frac{n-1}{2})(n-1)=n^2-2n+1</math> is a factor of <math>n!</math>. Also, <math>(n-2)(n)=n^2-2n</math> is a factor of <math>n!</math>. Since <math>2n<n^2-2n</math> for all <math>n\geq7</math>, we can use [[Bertrand's Postulate]] to show that there is at least one prime number <math>p</math> such that <math>n<p<n^2-2n</math>. Since we have two consecutive factors of <math>n!</math> and a prime number between the smaller of these factors and <math>n</math>, the condition will not be satisfied for all odd <math>n | + | If <math>n\geq7</math> is odd, then <math>(2)(\frac{n-1}{2})(n-1)=n^2-2n+1</math> is a factor of <math>n!</math>. Also, <math>(n-2)(n)=n^2-2n</math> is a factor of <math>n!</math>. Since <math>2n<n^2-2n</math> for all <math>n\geq7</math>, we can use [[Bertrand's Postulate]] to show that there is at least one prime number <math>p</math> such that <math>n<p<n^2-2n</math>. Since we have two consecutive factors of <math>n!</math> and a prime number between the smaller of these factors and <math>n</math>, the condition will not be satisfied for all odd <math>n\geq7%. |
− | If <math>n\geq8< | + | If </math>n\geq8<math> is even, then </math>(2)(\frac{n-2}{2})(n-2)=n^2-4n+4<math> is a factor of </math>n!<math>. Also, </math>(n-3)(n-1)=n^2-4n+3<math> is a factor of </math>n!<math>. Since </math>2n<n^2-4n+3<math> for all </math>n\geq8<math>, we can use Bertrand's Postulate again to show that there is at least one prime number </math>p<math> such that </math>n<p<n^2-4n+3<math>. Since we have two consecutive factors of </math>n!<math> and a prime number between the smaller of these factors and </math>n<math>, the condition will not be satisfied for all even </math>n\geq8<math>. |
− | Therefore, the only numbers that work are <math>n=3< | + | Therefore, the only numbers that work are </math>n=3<math> and </math>n=4$. |
~alexanderruan | ~alexanderruan |
Revision as of 23:31, 11 April 2024
Find all integers such that the following property holds: if we list the divisors of in increasing order as , then we have
Solution (Explanation of Video)
We can start by verifying that and work by listing out the factors of and . We can also see that does not work because the terms , and are consecutive factors of . Also, does not work because the terms , and appear consecutively in the factors of .
Note that if we have a prime number and an integer such that both and are factors of , then the condition cannot be satisfied.
If is odd, then is a factor of . Also, is a factor of . Since for all , we can use Bertrand's Postulate to show that there is at least one prime number such that . Since we have two consecutive factors of and a prime number between the smaller of these factors and , the condition will not be satisfied for all odd $n\geq7%.
If$ (Error compiling LaTeX. Unknown error_msg)n\geq8(2)(\frac{n-2}{2})(n-2)=n^2-4n+4n!(n-3)(n-1)=n^2-4n+3n!2n<n^2-4n+3n\geq8pn<p<n^2-4n+3n!nn\geq8$.
Therefore, the only numbers that work are$ (Error compiling LaTeX. Unknown error_msg)n=3n=4$.
~alexanderruan
Video Solution
https://youtu.be/ZcdBpaLC5p0 [video contains problem 1 and problem 4]