1. The series converges.

    1. Factorials suggest the ratio test. The only trick is to simplify the numerator of a_n by                         factoring a 2 out of factor and grouping them together, so 2⋅4⋅ … ⋅(2n) = 2ⁿn! Then after               simplification a_n+1/a_n= (2ⁿ⁺¹/2ⁿ)⋅((n+1)!/(n!))⋅((2n)!/(2n+2)!) = (2(n+1)((2n)!))/((2n+2)(2n+1)                 ((2n)!)) = 1/(2n+1) This → 0 as n → ∞, so the series converges by the Ratio Test.

    1. The series converges.

    1. The presence of n in exponents suggests the Root Test. The trick is to recognize the                        denominator is 2ⁿ(²)= (2ⁿ)ⁿ, so an can be rewritten as (nⁿ)/((2ⁿ)ⁿ)= (n/2ⁿ)ⁿ Then (a_n)^1/n= n/2ⁿ.          Replacing n with x and applying l’Hopital’s rule, we see: lim_{n → ∞}(a_n)1/n = 0 so the series                converges by the Root Test.

    1. The series diverges.

    1.  Factorials suggest the ratio test. Grouping like factors together we find a_n+1/a_n=                               ((3n+3)!/(3n)!)⋅(n!/(n+1)!)⋅((2n)!/(2n+2)!) Canceling common factors gives a_n+1/a_n= ((3n+3)               (3n+2)(3n+1))/((n+1)(2n+1)(2n+2)) = (27n³ + quadratic and lower terms)/(4n³ + quadratic                 and lower terms) As n → ∞, the cubic terms dominate, so lim_{n → ∞}a_n+1/a_n= 27/4. The series           diverges by the Ratio Test.