Geometric and bond frustration in transverse field Ising clusters (2311.04553v1)

Abstract: The Ising model, often seen as the paradigmatic spin model, has been heavily studied for its mathematical description of ferromagnetism in statistical mechanics. We explore a quantum version of this model, the transverse field Ising model, and investigate how the quantum property of magnetization fluctuates with geometrical frustration, a phenomenon arising from the geometry of a spin system's ground state. We introduce a general measure for frustration and then implement a computational model built in Python that translates spin lattices into adjacency matrices, solves the spectrum of the transverse field Ising model, calculates the expected magnetization of the ground state, plots the variable over randomly generated spin systems with controllable degrees of geometrical frustration, and compares the evolution of these plots over an increasing transverse field. Our finite-size studies exhibit an expected decrease in magnetization with increasing frustration and suggest the possibility of robust phases in the large N limit over finite ranges of frustration, which may be precursors to spin liquids or spin glasses.