(This is the 19. Let G be a group, and let H be a subgroup with [G: H] = 8. If g E G has odd order (i.e., ord (g) is odd), then g E H.

Number 19

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filling in the details to establish the equality 12. Let G be a non-commutative group with 343 elements. Let Z be the center of G and assume Z # {}. How many elements must Z contain? Explain your reasoning. 13. Let G be a group, and let Z be the center of G. Explain why [G: Z] is not a prime number. 14. Prove: Let G be a finite group (so each g E G has finite order), and let H be a subgroup of G. If G/H has an element of order n, then G has an element of order n. 15. (a) Write the contrapositive of the implication in Theorem 23.7. (b) Explain how G = D4 serves as an example of the contrapositive from part (a). 16. Prove: Let G be a commutative group, and let H be its subgroup. If every element h E H is a square in H (i.e., h = k² for some k € H) and every element aH = G/H is a square in G/H (i.e., aH = (bH)2 for some bH = G/H), then every element of G is a square in G. 17. Prove: Let G be a group, and let H be its subgroup. Suppose every element of H and G/H has order 3" where n is a non-negative integer. Then every element of G also has order 3" where n ≥ 0. 18. Let H be a subgroup of G with [G: H] = 2. Prove that aH = Ha for all a € G. (This is the statement of Theorem 24.10.) 19. Let G be a group, and let H be a subgroup with [G: H] = 8. If g E G has odd order (i.e., ord (g) is odd), then g € H.