PRODD 2 Determine whether the integer 701 is divisors. Do the same for the integer 1 Sieve of

Question 1

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upto Squ PROBLEMS 3.2 Determine whether the integer 701 is prime by testing all primes p < 701 as possible divisors. Do the same for the integer 1009. Employing the Sieve of Eratosthenes, obtain all the primes between 100 and 200. Z Given that p X n for all primes p < In, show that n > 1 is either a prime or the product of two primes. [Hint: Assume to the contrary that n contains at least three prime factors.] 4 Establish the following facts: (a) p is irrational for any prime p. (b) If a is a positive integer and a is rational, then a must be an integer. (c) For n > 2, /n is irrational. [Hint: Use the fact that 2" > n.] 5. Show that any composite three-digit number must have a prime factor less than or equal to 31. 6. Fill in any missing details in this sketch of a proof of the infinitude of primes: Assume that there are only finitely many primes, say p1, P2, ..., Pn. Let A be the product of any r of these primes and put B not both. Because A + B > 1, A + B has a prime divisor different from any of the pk, which is a contradiction. = PiP2· Pn/A. Then each pk divides either A or B, but 1. Modify Euclid's proof that there are infinitely many primes by assuming the existence Of a largest prime p and using the integer = p! + 1 to arrive at a contradiction. 0. Give another proof of the infinitude of primes by assuming that there are only finitely many || Primes, say pi, P2, . .. , pn, and using the following integer to arrive at a contradiction: