Number theory test pending
Q1. Does there exist a natural number “(n)” such that (n^2 + n + 1) is divisible by (1955)? If “Yes”, provide an example and if “No”, provide a valid proof. S1. n^2 + n + 1 = 0 mod 5 (if it's div by 1955, it's also div by 5) n^2 + n = 4 mod 5 Let's check all possible remainders of n with 5. n = 0 mod 5 No. n = 1 no. n = 2 4 + 2 = 1 mod 5 n = 3 9 + 3 = 2 mod 5 n = 4 16 + 4 = 0 mod 5 So nothing works. "No". Q3. Using the properties of congruences, prove that 89 | 2^44 - 1 and 97 | 2^48 - 1 S3. 2^44 - 1= 0 mod 89 (2^11 - 1)(2^11 + 1)(2^22 + 1) = 0 mod 89 Since 89 is a prime, one of these factors has to be a multiple of 89. Let's test one by one. 2^11 = 1 mod 89. 2^5.2^6.3 = 3 mod 89 96.64 = 3 mod 89 = 7.64 = 448 = 3 mod 89 H.P. Part 2: 2^48 - 1 = 0 mod 97 = (2^6 - 1)(2^6 + 1)(2^12 + 1)(2^24 + 1) First 2 factors are small. Next: 2^12 + 1 = 0 => 2^12 = -1 mod 97 = 96 mod 97 = 32.128 => 128 = 3 mod 97 which is wrong Next: 2^24 = -1 = 96 mod 97 2^19 = 3 mod 97 ...