Answer to Question #203298 in Abstract Algebra for Raghav

Let "G" be a finite group. Let us show that the number of elements "g\\in G" such that "g^3= e" is

odd, where "e" is the identity of "G". If "g^3=e", then "(g^{-1})^3=g^{-3}=(g^3)^{-1}=e^{-1}=e". Let us find all "g\\in G" such that "g^3=e" and "g^{-1}=g." In this case "g^2=e," and hence "g=ge=gg^2=g^3=e."  Therefore, for all non-identity elements "g" with "g^3=e" we have that "(g^{-1})^3=e" and the set "\\{g,g^{-1}\\}" is of cardinality 2. Since "e^3=e" and "|\\{g,g^{-1}\\}|=2" for "g\\in G\\setminus\\{e\\}" and "g^3=e", we conclude that the number of elements "g\\in G" such that "g^3= e" is equal to  "|\\{e\\}\\cup(\\bigcup\\limits_{g\\in G\\setminus\\{e\\},\\ g^3=e}\\{g,g^{-1}\\})|=1+2k" (where "k" is a number of different pairs "\\{g,g^{-1}\\}"), and hence is odd.