I am having a confusion in this question-
What is the remainder when $7^{103}$ is divided by 24?
I attempted it as follows - It can be written as
$(7^2)^{51} \cdot 7$
Which can be written as
$(24*2+1)^{51} \cdot 7$
Now using Binomial Theorem clearly the remainder should be $1^1 \cdot 7=7$
But the answer in most places is 18 and whereas in some sites it is 7!!
Which one is correct and why am I wrong if I am?
PS-for those who think i am correct please prove that they are wrong:)
Check this one out also... you have to download the pdf and scroll down to almost the middle to find the question! https://www.google.co.in/url?sa=t&source=web&rct=j&ei=dVwUVeKtDoKyuATQ6IH4DA&url=http://www.arbindsingh.com/wp-content/uploads/2012/07/Introduction-To-Binomial-Theorem.pdf&ved=0CC8QFjAG&usg=AFQjCNGErAyk6Qh_fO2nlD-XvlDyuMFblQ&sig2=HiEovIrDxhZy4DPIgGHA_w
Your reasoning is correct. The remainder is $7$.
If you want another way to check, we can use modular arithmetic. This is where in arithmetic you replace a number by its remainder (with respect to $24$ in this case).
As you have shown, $7^2$ has remainder 1 modulo 24. This means $$7^{103} \equiv 7^{102} \cdot 7 \equiv 1^{51} \cdot 7 \equiv 7 \mod 24.$$
If you want, I can spell out the binomial expansion.
When you expand $(2\cdot 24 + 1)^{51}$, the result is: $$_{51}C_0 (2\cdot 24)^{51} +\ _{51}C_{1} (2 \cdot 24)^{50} + \cdots +\ _{51}C_{50} (2\cdot 24) +\ _{51}C_{51}$$
Since $24$ is attached to all but the last term, and $_{51}C_{51} = 1$, we have $$(2\cdot 24 + 1)^{51} = 24 \cdot M + 1$$
This means $$7 \cdot (2\cdot 24 + 1)^{51} = (7M)\cdot 24 + 7$$ and so the remainder after division by $24$ is $7$.