Quantum geometrical bound relations for observables

The quantum geometric tensor (QGT) provides nontrivial bound relations among physical quantities, as exemplified by the metric-curvature inequality. In this paper, we investigate various bound relations for different observables through certain generalizations of the QGT. First, by generalizing the parameter space, we demonstrate that bound relations hold for all linear responses. As an application, we show the thermodynamic inequality originating from the convexity of free energy can be further tightened. Second, by extending the projection operator, we establish a bound relation between the Drude weight and the orbital magnetization. The equality is exactly satisfied in the Landau level system, and systems with nearly flat bands tend to approach equality as well. We apply the resulting inequality to two orbital ferromagnets and support that the twisted bilayer graphene system is close to the Landau level system. Moreover, we show that an analogous inequality also holds for a higher-order multipole, magnetic quadrupole. Finally, we discuss the analogy between the QGT and the uncertainty principle, emphasizing that the existence of nontrivial bound relations necessarily reflects quantum effects.