For any positive integers n prove that n^3-n is divisible by 6
Answers
Answer:
Step-by-step explanation:
→ n³ - n = n(n²-1) = n(n -1)(n + 1) is divided by 3 then possible reminder is 0, 1 and 2 [ ∵ if P = ab + r , then 0 ≤ r < a by Euclid lemma ]
→ ∴ Let n = 3r , 3r +1 , 3r + 2 , where r is an integer
→ Case 1 :- when n = 3r
→ Then, n³ - n is divisible by 3 [∵n³ - n = n(n-1)(n+1) = 3r(3r-1)(3r+1) , clearly shown it is divisible by 3 ]
→ Case2 :- when n = 3r + 1
e.g., n - 1 = 3r +1 - 1 = 3r
→ Then, n³ - n = (3r + 1)(3r)(3r + 2) , it is divisible by 3
→ Case 3:- when n = 3r - 1
e.g., n + 1 = 3r - 1 + 1 = 3r
→ Then, n³ - n = (3r -1)(3r -2)(3r) , it is divisible by 3
→ From above explanation we observed n³ - n is divisible by 3 , where n is any positive integers .
Step-by-step explanation:
▶ n³ - n = n (n² - 1) = n (n - 1) (n + 1)
Whenever a number is divided by 3, the remainder obtained is either 0 or 1 or 2.
∴ n = 3p or 3p + 1 or 3p + 2, where p is some integer.
If n = 3p, then n is divisible by 3.
If n = 3p + 1, then n – 1 = 3p + 1 –1 = 3p is divisible by 3.
If n = 3p + 2, then n + 1 = 3p + 2 + 1 = 3p + 3 = 3(p + 1) is divisible by 3.
So, we can say that one of the numbers among n, n – 1 and n + 1 is always divisible by 3.
⇒ n (n – 1) (n + 1) is divisible by 3.
Similarly, whenever a number is divided 2, the remainder obtained is 0 or 1.
∴ n = 2q or 2q + 1, where q is some integer.
If n = 2q, then n is divisible by 2.
If n = 2q + 1, then n – 1 = 2q + 1 – 1 = 2q is divisible by 2 and n + 1 = 2q + 1 + 1 = 2q + 2 = 2 (q + 1) is divisible by 2.
So, we can say that one of the numbers among n, n – 1 and n + 1 is always divisible by 2.
⇒ n (n – 1) (n + 1) is divisible by 2.
Since, n (n – 1) (n + 1) is divisible by 2 and 3.
∴ n ( n - 1 ) ( n + 1 ) = n³ - n is divisible by 6.( If a number is divisible by both 2 and 3 , then it is divisible by 6)
✔✔ Hence, it is solved ✅✅.