The centre of a finite p-group is grater than the identity alone

Is it possible for a group G to contain a non-identity element of finite order and...

Is it possible for a group G to contain a non-identity element of finite order and also an element of infinite order? If yes, illustrate with an example. If no, give a convincing explanation for why it is not possible.

: (a) Let p be a prime, and let G be a finite Abelian group. Show...

: (a) Let p be a prime, and let G be a finite Abelian group. Show that Gp = {x ∈ G | |x| is a power of p} is a subgroup of G. (For the identity, remember that 1 = p 0 is a power of p.) (b) Let p1, . . . , pn be pair-wise distinct primes, and let G be an Abelian group. Show that Gp1 , . . . , Gpn form direct sum in...

Let G be a finite group and let P be a Sylow p-subgroup of G. Suppose...

Let G be a finite group and let P be a Sylow p-subgroup of G. Suppose H is a normal subgroup of G. Prove that HP/H is a Sylow p-subgroup of G/H and that H ∩ P is a Sylow p-subgroup of H. Hint: Use the Second Isomorphism theorem.

(b) If H is a p-subgroup of a finite group G, prove that H is contained...

(b) If H is a p-subgroup of a finite group G, prove that H is contained in a Sylow p-subgroup of G. [Hint: Consider the H-conjugacy class equation for the set of all Sylowp-subgroups of G.]

Group Theory Question: Show that if a finite group G with 6 elements is not abelian,...

Group Theory Question: Show that if a finite group G with 6 elements is not abelian, then it must be the group of symmetries of an equilateral triangle. Can one have a similar statement for a finite group G of eight elements?

Let G be a finite group and let H, K be normal subgroups of G. If...

Let G be a finite group and let H, K be normal subgroups of G. If [G : H] = p and [G : K] = q where p and q are distinct primes, prove that pq divides [G : H ∩ K].

1(a) Suppose G is a group with p + 1 elements of order p , where...

1(a) Suppose G is a group with p + 1 elements of order p , where p is prime. Prove that G is not cyclic. (b) Suppose G is a group with order p, where p is prime. Prove that the order of every non-identity element in G is p.

Let G be a finite group. There are 2 ways of getting a subgroup of G,...

Let G be a finite group. There are 2 ways of getting a subgroup of G, which are {e} and G. Now, prove the following : If |G|>1 is not prime, then G has a subgroup other than the 2 groups which are mentioned in the above.

Can there be an element of infinite order in a finite group? Prove or disprove.

Can there be an element of infinite order in a finite group? Prove or disprove.

Let p(x) be an irreducible polynomial of degree n over a finite field K. Show that...

Let p(x) be an irreducible polynomial of degree n over a finite field K. Show that its Galois group over K is cyclic of order n and then show how the Galois group of x3 − 1 over Q is cyclic of order 2.