Sums of powers of integers via differentiation

Abstract

For integer k ≥ 0, let Sk denote the sum of the kth powers of the first n positive integers 1k + 2k + ·s + nk. For any given k, the power sum Sk can in principle be determined by differentiating k times (with respect to x) the associated exponential generating function Σk=0∞Sk xk/k!, and then taking the limit of the resulting differentiated function as x approaches 0. In this paper, we exploit this method to establish a couple of seemingly novel recurrence relations, one of them involving the even-indexed power sums S2, S4,…, S2k, and the other the odd-indexed power sums S1, S3, …, S2k-1, with both recurrence relations depending explicitly on the parameter N = n + 12. From this, we obtain a determinantal formula of order k which yields S2k [S2k-1] in the Faulhaber form, that is, as an odd [even] polynomial in N. As a byproduct, we discover a new determinantal formula for the Bernoulli number B2k. Furthermore, we show that S2k and S2k-1 can be obtained by taking the corresponding higher order derivatives of the Chebyshev polynomials of the second kind.