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Question
Prove that one of any three consecutive positive integers must be divisible by 3.
Solution
Let three consecutive positive integers are n, n + 1 and n + 2.
On dividing n by 3, let q be the quotient and r be the remainder.
Then, by Euclid’s division algorithm,
n = 3q + r, where 0 ≤ r < 3
`\implies` n = 3q or n = 3q + 1 or n = 3q + 2
Case I: If n = 3q, which is divisible by 3
But (n + 1) and (n + 2) are not divisible by 3.
So, in this case, only n is divisible by 3.
Case II: If n = 3q + 1,
Then n + 2 = 3q + 3 = 3(q + 1) which is divisible by 3
But n and (n + 1) are not divisible by 3.
So, in this case, only (n + 2) is divisible by 3.
Case III: If n – 3q + 2,
Then n + 1 = 3q + 3 = 3(q + 1) which is divisible by 3
But n and (n + 2) are not divisible by 3.
So, in this case, only (n + 1) is divisible by 3.
Hence, one of any three consecutive positive integers must be divisible by 3.
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