Difference between revisions of "2007 USAMO Problems/Problem 5"
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== Problem == | == Problem == | ||
| − | Prove that for every nonnegative integer <math>n</math>, the number <math>7^{7^n}+1</math> is the product of at least <math>2n+3</math> (not necessarily distinct) | + | Prove that for every [[nonnegative]] [[integer]] <math>n</math>, the number <math>7^{7^n}+1</math> is the [[product]] of at least <math>\displaystyle 2n+3</math> (not necessarily distinct) [[prime]]s. |
| + | __TOC__ | ||
== Solution == | == Solution == | ||
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We prove the result by induction. | We prove the result by induction. | ||
Let <math>\displaystyle{a_{n}}</math> be <math>7^{7^{n}}+1</math>. The result holds for <math>\displaystyle{n=0}</math> because <math>\displaystyle{a_0 = 2^3}</math> is the product of <math>\displaystyle{3}</math> primes. | Let <math>\displaystyle{a_{n}}</math> be <math>7^{7^{n}}+1</math>. The result holds for <math>\displaystyle{n=0}</math> because <math>\displaystyle{a_0 = 2^3}</math> is the product of <math>\displaystyle{3}</math> primes. | ||
| − | Now we assume the result holds for <math>\displaystyle{n}</math>. Note that <math>\displaystyle{a_{n}}</math> satisfies the recursion | + | Now we assume the result holds for <math>\displaystyle{n}</math>. Note that <math>\displaystyle{a_{n}}</math> satisfies the [[recursion]] |
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| + | === Solution 1 === | ||
| + | <div style="text-align:center;"><math>\displaystyle{a_{n+1}= (a_{n}-1)^{7}+1} = a_{n}\left(a_{n}^{6}-7(a_{n}-1)(a_{n}^{2}-a_{n}+1)^{2}\right)</math></div> | ||
Since <math>\displaystyle{a_n - 1}</math> is an odd power of <math>\displaystyle{7}</math>, <math>\displaystyle{7(a_n-1)}</math> is a perfect square. Therefore <math>\displaystyle{a_{n}^{6}-7(a_{n}-1)(a_{n}^{2}-a_{n}+1)^{2}}</math> is a difference of squares and thus composite, i.e. it is divisible by <math>\displaystyle{2}</math> primes. By assumption, <math>\displaystyle{a_n}</math> is divisible by <math>\displaystyle{2n + 3}</math> primes. Thus <math>\displaystyle{a_{n+1}}</math> is divisible by <math>\displaystyle{2+ (2n + 3) = 2(n+1) + 3}</math> primes as desired. | Since <math>\displaystyle{a_n - 1}</math> is an odd power of <math>\displaystyle{7}</math>, <math>\displaystyle{7(a_n-1)}</math> is a perfect square. Therefore <math>\displaystyle{a_{n}^{6}-7(a_{n}-1)(a_{n}^{2}-a_{n}+1)^{2}}</math> is a difference of squares and thus composite, i.e. it is divisible by <math>\displaystyle{2}</math> primes. By assumption, <math>\displaystyle{a_n}</math> is divisible by <math>\displaystyle{2n + 3}</math> primes. Thus <math>\displaystyle{a_{n+1}}</math> is divisible by <math>\displaystyle{2+ (2n + 3) = 2(n+1) + 3}</math> primes as desired. | ||
| + | == See also == | ||
{{USAMO newbox|year=2007|num-b=4|num-a=6}} | {{USAMO newbox|year=2007|num-b=4|num-a=6}} | ||
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| + | [[Category:Olympiad Algebra Problems]] | ||
Revision as of 15:30, 26 April 2007
Problem
Prove that for every nonnegative integer 
, the number 
is the product of at least 
(not necessarily distinct) primes.
Contents
Solution
We prove the result by induction.
Let 
be 
. The result holds for 
because 
is the product of 
primes.
Now we assume the result holds for 
. Note that satisfies the recursion
Solution 1
Since 
is an odd power of 
, 
is a perfect square. Therefore 
is a difference of squares and thus composite, i.e. it is divisible by 
primes. By assumption, 
is divisible by 
primes. Thus 
is divisible by 
primes as desired.
See also
| 2007 USAMO (Problems • Resources) | ||
| Preceded by Problem 4 |
Followed by Problem 6 | |
| 1 • 2 • 3 • 4 • 5 • 6 | ||
| All USAMO Problems and Solutions | ||
