On some critical Riemannian metrics and Thorpe-type conditions

Abstract

We study critical metrics of higher-order curvature functionals on compact Riemannian n-manifolds (M,g). For an integer k with 2 ≤ 2k ≤ n, let Rk denote the k-th exterior power of the Riemann curvature tensor. We investigate the Riemannian functionals \[H2k(g)=∫M tr(Rk)\,dvolg G2k(g)=∫M \|Rk\|2\,dvolg,\] which generalize the Hilbert--Einstein functional and the total squared norm curvature, obtained for k=1 respectively. Using the formalism of double forms, we develop a systematic variational framework yielding compact first variation formulas for these functionals. Two key lemmas streamline the variational computations. A central technical ingredient is a generalization of the classical Lanczos identity to symmetric double forms of arbitrary even degree, providing explicit algebraic relations between the tensors 2k-1(Rk Rk) and 4k-1(R2k). As a main geometric application, we introduce (2k)-Thorpe and (2k)-anti-Thorpe metrics, defined by self-duality and anti-self-duality conditions on gr-2kRk in even dimensions n=2r. In the critical dimension n=4k, these metrics are absolute minimizers of G2k, with the minimum determined by the Euler characteristic. For n>4k, they satisfy a harmonicity property leading to rigidity results under suitable curvature positivity assumptions. We further establish equivalences among variational criticality conditions. For hyper-(2k)-Einstein metrics, characterized by Rk=λ g2k-1, being critical for G2k is equivalent to being (4k)-Einstein and to being weakly (2k)-Einstein. In the locally conformally flat setting, we classify all 4-Thorpe metrics, showing that they are either space forms or Riemannian products Sr(c) × Hr(-c).