The entropy of a quantum system is a measure of its randomness and is useful in quantifying entanglement. We study the problem of measuring the von Neumann and Rényi entropies of an unknown mixed quantum state given access to independent copies of the state. For Rényi entropy of integral order exceeding one, we determine the order-optimal copy complexity and show that it is strictly lower than the number of copies required to learn the underlying state. The main technical innovation is a concentration result for certain polynomials that arise in the Kerov algebra of Young diagrams, which is proven using the cycle structure of compositions of certain types of permutations. For von Neumann entropy and Rényi entropy of non-integral orders, we provide upper and lower bounds on the sample complexity of the Empirical Young Diagram (EYD) algorithm, which is the analogue of the empirical plug-in estimator in classical estimation.