Abstract
We study the Killing vectors of the quantum ground-state manifold of a parameter-dependent Hamiltonian. We find that the manifold may have symmetries that are not visible at the level of the Hamiltonian and that different quantum phases of matter exhibit different symmetries. We propose a Bianchi-based classification of the various ground-state manifolds using the Lie algebra of the Killing vector fields. Moreover, we explain how to exploit these symmetries to find geodesics and explore their behaviour when crossing critical lines. We briefly discuss the relation between geodesics, energy fluctuations and adiabatic preparation protocols. Our primary example is the anisotropic transverse-field Ising model. We also analyze the Ising limit and find analytic solutions to the geodesic equations for both cases.
Highlights
In recent years, there has been an increasing interest in the study of the geometry of quantum states of quantum many-body systems
We have studied the symmetries of the ground-state manifold of the transversefield Ising model (TFIM) for both the anisotropic and the isotropic case
We encountered a hidden symmetry in the ferromagnetic sector of the manifold
Summary
There has been an increasing interest in the study of the geometry of quantum states of quantum many-body systems. Note that its derivation is entirely generic and does not rely on any adiabatic assumptions These two complementary parts of the QGT provide a wealth of geometrical and topological structures to study quantum many-body systems. From this metric, we can construct geometric quantities such as Killing vectors, Riemann and Ricci tensors, scalar curvatures, et cetera. We can construct geometric quantities such as Killing vectors, Riemann and Ricci tensors, scalar curvatures, et cetera Whereas both the real and imaginary parts provide us with topological data of the quantum parameter manifold like the Euler and Chern (or Chern-Simons, depending on dimensionality) invariants.
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