We know 333333 = 3 * 111111
Now the number which is 111111 or $\frac{10^6-1}{9}$
Any number which is having 1's is $\frac{10^n-1}{9}$
$\frac{10^6-1}{9}$ shall divide $\frac{10^n-1}{9}$ only when n is multiple of 6
Or n = 6k for some integer k
Number is divisible by 111111 and 9 as GCD(111111, 9) = 333333
This is so because 111111 is divisible by 3 and 9 = 3* 3
So 6k should be divisible by 9 and smallest k = 3 or 6k = 18.
N = 6k = 18
We shall prove the same by construction. But before that set us try to understand the pattern
One digit number divisible by 5there is only one number 5 and the digit is odd
2 digit number divisible by $5^2=25$ the numbers are 25,50,75 and 75 has both digits odd
3 digit number divisible by $5^3=125$ the numbers are 125,250,375 and so on 375 has all there digits odd
4 digit number divisible by $5^4= 625$ I am not enumerating and a number 9375
We shall use this as a basis for construction of number by induction we shall expand the number from n digits to n+1 digits by adding a a digit to the left.
Let there be an n digit number with all n digits odd and divisible by $5^n$ and let it be $k*5^n$. Note that k has to be odd else digit in unit place shall be zero which i even.
Now we know that $10^n$ is divisible by $5^n$
So adding $p *10^n$ we can convert the n digit number to n+1 digit number and this is divisible by $5^n$.
We have n+1 digit number $p * 10^n + k * 5^n= (p *2 ^n + k) 5^n$
Now we require and do we have $p *2^n + k$ divisible by 5
That is $p * 2^n \equiv -k \pmod 5$
As 3 is multiplicative inverse of 2 we get
$p \equiv -k * 3^n \pmod 5$
p cannot be zero as $gcd(3,5) = 1$
So p is 1 or 2 or 3 or 5
If p is 1 or 3 then we are done
If p is 2 or 4 add 5 to p to get p single digit and odd
Out
of 65 numbers one can choose 2 numbers in ${65}\choose {2}$ 2080 ways.
We have 2080 pairs and when we divide by 2016 there can be 2016 remainders So there exists a, b and c,d such that dividing a + b by 2016 leaves the same remainder as c + d dividing by 2016.
Or a + b -c - d is divisible by 2016 . This is based on pigeon hole principle
Because product is bi-quadratic and one factor is quadratic so other factor must be quadratic
Other factor is of the form $x^2+ax+b$
So we get
$(x^2+2x+5)(x^2+ax+b) = = x^4 + (2+a)x^3 + (b+2a+5)x^2 + (2b+5a)x + 5b$
Comparing with $x^4+px^2+ q$ we get a = - 2 (coefficient $x^3$) and $b = 5$ from coefficient of x
So q = 5b = 25
Comparing coefficient of x^2 we get p = 5 -4 + 5 = 6
So Ans is (D) 6,25
Let us work mod 9.
We have $2^3 \equiv -1 \pmod 9$
Hence $2^{27} \equiv (-1)^9 \equiv -1 \pmod 9$
Hence $2^{29} \equiv (-1) * 4 \equiv -4 \pmod 9$
If we have all the digits(once) that is 10 digits then sum of digit is 45 so it is divisible by 9 or 0 mod 9
So removing 4 we shall have -4 mod 9.
So missing digit is 4
Solution
The above value = 8 * (k 8s) = 8 * 8 * (k ones) ths we find by taking 8 out
$= 64 * \frac{(10^k-1)}{9}$ as $(n) ones * 9 = \frac{10^n-1}{9}$
$= (7 *9 +1) * \frac{(10^k-1)}{9}$ as denominator is 9 we put 64 as multiple of 9 and plus 1
$ =7 * 9 * \frac{10^k-1}{9}+ \frac{10^k-1}{9}$ expanding
$ =7 * (10^k-1)+ \frac{10^k-1}{9}$
$ =7 * 10^k-7 + \frac{10^k-1}{9}$
$ =7 * 10^k + \frac{10^k-1}{9}-7 $
The 1st term gives 7 followed by k zeroes the 2nd term gives k ones and sum total shall be 7 followed by k ones. . when we subtract 4 we get 7 followed by k-2 zeroes followed by 04.
This gives sum of digits = 7 + k -2 + 4 = 1000
or = 991
so Answer is (D)
Basically we need to find n such that $5^n = -1 \pmod 7$
Now we have as 7 is a prime number as per Fermat's Little Theorem $5^6 \equiv 1 \pmod 7$
So $5^{6k} \equiv 1 \pmod 7$
Now as $5^6 \equiv 1 \pmod 7$ so we need to check for power of 5 to a factor of 6 that is 1 or 2 or 3
$5^1,5^2$ do not satisfy and $5^3 \equiv -1 \pmod 7$ satisfies.
so $n \in 6k+3 $ for all $k \in \mathbb{N}$
