“…GQTG densities possess a series of interesting properties which have been studied in many papers and appear summarized in some detail e.g., in [1]. Among the most relevant ones, we can mention: i) when linearized around any maximally symmetric background, their equations are identical to the Einstein gravity ones, up to a redefinition of the Newton constant -in other words, they only propagate the usual transverse and traceless graviton in the vacuum [4][5][6][7][8][9][10]; 2 ii) they possess non-hairy black hole solutions fully characterized by their ADM mass/energy and whose thermodynamic properties can be obtained from an algebraic system of equations; iii) at least in D = 4, black holes generically become thermodynamically stable below certain mass [10]; iv) in addition to black holes, certain subsets of GQTGs also contain Taub-NUT/Bolt solutions characterized by a single metric function and analytic thermodynamics [17]; v) when evaluated on a Friedmann-Lemaître-Robertson-Walker (FLRW) ansatz, certain GQTGs in D = 4 also give rise to second-order equations for the scale factor, with intriguing consequences regarding cosmological evolution [21][22][23]; vi) we can consider arbitrary linear combinations of GQTG densities and the corresponding properties hold, which means, in particular, that GQTG theories have a well-defined and continuous Einstein gravity limit, corresponding to setting all higher-curvature couplings to zero.…”