Let $a_n$ be the $n^{th}$ term of an A.P. If $S_n = a_1 + a_2 + a_3 + \ldots + a_n = 700$, $a_6 = 7$ and $S_7 = 7$, then $a_n$ is equal to :

<p><p><strong>Sum of n terms of an AP ($S_n$):</strong> $S_n = \frac{n}{2} [2a + (n-1)d]$ where 'a' is the first term and 'd' is the common difference.</p></p> <p><p><strong>nth term of an AP ($a_n$):</strong> $a_n = a + (n-1)d$</p></p> <p><strong>Given Information:</strong></p> <p><p>$S_n = 700$ (The sum of the first n terms is 700)</p></p> <p><p>$a_6 = 7$ (The 6th term is 7)</p></p> <p><p>$S_7 = 7$ (The sum of the first 7 terms is 7)</p></p> <p><strong>Steps to Solve:</strong></p> <p><p><strong>Use $S_7$ to find a relationship between 'a' and 'd':</strong></p> <p><p>$S_7 = \frac{7}{2} [2a + (7-1)d] = 7$</p></p> <p><p>$\frac{7}{2} [2a + 6d] = 7$</p></p> <p><p>$2a + 6d = 2$</p></p> <p><p>$a + 3d = 1$ <strong>(Equation 1)</strong></p></p></p> <p><p><strong>Use $a_6$ to find another relationship between 'a' and 'd':</strong></p> <p><p>$a_6 = a + (6-1)d = 7$</p></p> <p><p>$a + 5d = 7$ <strong>(Equation 2)</strong></p></p></p> <p><p><strong>Solve the system of equations (Equation 1 and Equation 2) to find 'a' and 'd':</strong></p> <p><p>Subtract Equation 1 from Equation 2:</p> <p><p>$(a + 5d) - (a + 3d) = 7 - 1$</p></p> <p><p>$2d = 6$</p></p> <p><p>$d = 3$</p></p></p> <p><p>Substitute d = 3 into Equation 1:</p> <p><p>$a + 3(3) = 1$</p></p> <p><p>$a + 9 = 1$</p></p> <p><p>$a = -8$</p></p></p></p> <p><p><strong>Find 'n' using $S_n = 700$:</strong></p> <p><p>$S_n = \frac{n}{2} [2a + (n-1)d] = 700$</p></p> <p><p>$\frac{n}{2} [2(-8) + (n-1)(3)] = 700$</p></p> <p><p>$n[-16 + 3n - 3] = 1400$</p></p> <p><p>$n[3n - 19] = 1400$</p></p> <p><p>$3n^2 - 19n - 1400 = 0$</p></p></p> <p><p><strong>Solve the quadratic equation for 'n':</strong></p> <p><p>We can use the quadratic formula: $n = \frac{-b \pm \sqrt{b^2 - 4ac}}{2a}$</p></p> <p><p>$n = \frac{19 \pm \sqrt{(-19)^2 - 4(3)(-1400)}}{2(3)}$</p></p> <p><p>$n = \frac{19 \pm \sqrt{361 + 16800}}{6}$</p></p> <p><p>$n = \frac{19 \pm \sqrt{17161}}{6}$</p></p> <p><p>$n = \frac{19 \pm 131}{6}$</p></p> <p><p>We have two possible values for n:</p> <p><p>$n = \frac{19 + 131}{6} = \frac{150}{6} = 25$</p></p> <p><p>$n = \frac{19 - 131}{6} = \frac{-112}{6} = -\frac{56}{3}$ (Since 'n' must be a positive integer, we discard this solution)</p></p></p> <p><p>So, $n = 25$</p></p></p> <p><p><strong>Find $a_n$ (which is $a_{25}$):</strong></p> <p><p>$a_{25} = a + (25-1)d$</p></p> <p><p>$a_{25} = -8 + (24)(3)$</p></p> <p><p>$a_{25} = -8 + 72$</p></p> <p><p>$a_{25} = 64$</p></p></p> <p>Therefore, $a_n = 64$. The correct answer is Option D.</p>