First Order Transitions Between the Gapped Spin-Liquid and Ferrimagnetic Phases in (1/2,1/2,1) Mixed Diamond Chains with Bond Alternation

Abstract

The ground-state phases of mixed diamond chains with bond alternation δ, and (S, τ(1), τ(2))=(1/2,1/2,1), where S is the magnitude of vertex spins, and τ(1) and τ(2) are those of apical spins, are investigated. The two apical spins in each unit cell are connected by an exchange coupling λ. The exchange couplings between the apical spins and the vertex spins take the values 1+δ and 1-δ alternatingly. This model has an infinite number of local conservation laws. For large λ and δ ≠ 0, the ground state is equivalent to that of the spin 1/2 chain with bond alternation. Hence, the ground state is a gapped spin liquid. This energy gap vanishes for δ=0. With the decrease of λ, the ground state undergoes a transition at λ=λ c0(δ) to a series of ferrimagnetic phases with a spontaneous magnetization m sp=1/p per unit cell where p is a positive integer. It is found that this transition is a first order transition for δ≠ 0 with a discontinuous change in m sp, while no discontinuity is found for δ=0. The critical behaviors of m sp and λ c0(δ) around the critical point (δ,λ) =(0, λ c0(δ)) are also discussed analytically.