Find all isomorphism classes for albelian groups of order p2q3r4, where p,q, and r are prime.

Let p be a prime number. Prove that there are exactly two groups of order p^2...

Let p be a prime number. Prove that there are exactly two groups of order p^2 up to isomorphism, and both are abelian. (Abstract Algebra)

Let p and q be any two distinct prime numbers and define the relation a R...

Let p and q be any two distinct prime numbers and define the relation a R b on integers a,b by: a R b iff b-a is divisible by both p and q. For this relation R: Show that the equivalence classes of R correspond to the elements of  ℤpq. That is: [a] = [b] as equivalence classes of R if and only if [a] = [b] as elements of ℤpq. you may use the following lemma: If p is prime...

For each prime number p below, find all of the Gaussian primes q such that p...

For each prime number p below, find all of the Gaussian primes q such that p lies below q: 2 3 5 Then for each Gaussian prime q below, find the prime number p such that q lies above p: 1 + 4i 3i 2 + 3i

Let p and q be any two distinct prime numbers and define the relation a R...

Let p and q be any two distinct prime numbers and define the relation a R b on integers a,b by: a R b iff b-a is divisible by both p and q. I need to prove that: a) R is an equivalence relation. (which I have) b) The equivalence classes of R correspond to the elements of  ℤpq. That is: [a] = [b] as equivalence classes of R if and only if [a] = [b] as elements of ℤpq I...

Prove that there are four groups of order 28 up to isomorphism.

Prove that there are four groups of order 28 up to isomorphism.

Let p and q be any two distinct prime numbers and define the relation a R...

Let p and q be any two distinct prime numbers and define the relation a R b on integers a,b by: a R b iff b-a is divisible by both p and q. For this relation R: Prove that R is an equivalence relation. you may use the following lemma: If p is prime and p|mn, then p|m or p|n

Prove there are exactly two groups of order 285 up to isomorphism. Determine their structure in...

Prove there are exactly two groups of order 285 up to isomorphism. Determine their structure in terms of semi-direct products of simple groups.

Let G be a group of order p^2, where p is a prime. Show that G...

Let G be a group of order p^2, where p is a prime. Show that G must have a subgroup of order p. please show with notation if possible

If G is a group of order (p^k)s where p is a prime number such that...

If G is a group of order (p^k)s where p is a prime number such that (p,s)=1, then show that each subgroup of order p^i ; i= 1,2...(k-1) is a normal subgroup of atleast one subgroup of order p^(i+1)

What are all the factor groups of the quaternion group Q8 up to isomorphism?

What are all the factor groups of the quaternion group Q8 up to isomorphism?