Slave boson

The slave boson method is a technique for dealing with models of strongly correlated systems, providing a method to second-quantize valence fluctuations within a restrictive manifold of states. In the 1960s the physicist John Hubbard introduced an operator, now named the "Hubbard operator"^[1] to describe the creation of an electron within a restrictive manifold of valence configurations. Consider for example, a rare earth or actinide ion in which strong Coulomb interactions restrict the charge fluctuations to two valence states, such as the Ce⁴⁺(4f⁰) and Ce³⁺ (4f¹) configurations of a mixed-valence cerium compound. The corresponding quantum states of these two states are the singlet ${\displaystyle |f^0⟩}$ state and the magnetic ${\displaystyle |f^1:\sigma ⟩}$ state, where ${\displaystyle \sigma =\uparrow ,\downarrow }$ is the spin. The fermionic Hubbard operators that link these states are then Template:NumBlk The algebra of operators is closed by introducing the two bosonic operators Template:NumBlk Together, these operators satisfy the graded Lie algebra Template:NumBlk where the ${\displaystyle [A,B{]}_{\pm }=AB\pm BA}$ and the sign is chosen to be negative, unless both ${\displaystyle A}$ and ${\displaystyle B}$ are fermions, in which case it is positive. The Hubbard operators are the generators of the super group SU(2|1). This non-canonical algebra means that these operators do not satisfy a Wick's theorem, which prevents a conventional diagrammatic or field theoretic treatment.

In 1983 Piers Coleman introduced the slave boson formulation of the Hubbard operators,^[2] which enabled valence fluctuations to be treated within a field-theoretic approach.^[3] In this approach, the spinless configuration of the ion is represented by a spinless "slave boson" ${\displaystyle |f^0⟩=b^{†}|0⟩}$, whereas the magnetic configuration ${\displaystyle |f^1:\sigma ⟩=f_{\sigma }^{†}|0⟩}$ is represented by an Abrikosov slave fermion. From these considerations, it is seen that the Hubbard operators can be written as Template:NumBlk and Template:NumBlk This factorization of the Hubbard operators faithfully preserves the graded Lie algebra. Moreover, the Hubbard operators so written commute with the conserved quantity Template:NumBlk In Hubbard's original approach, ${\displaystyle Q=1}$, but by generalizing this quantity to larger values, higher irreducible representations of SU(2|1) are generated. The slave boson representation can be extended from two component to ${\displaystyle N}$ component fermions, where the spin index ${\displaystyle \alpha \in [1,N]}$ runs over ${\displaystyle N}$ values. By allowing ${\displaystyle N}$ to become large, while maintaining the ratio ${\displaystyle Q/N}$, it is possible to develop a controlled large-${\displaystyle N}$ expansion.

The slave boson approach has since been widely applied to strongly correlated electron systems, and has proven useful in developing the resonating valence bond theory (RVB) of high temperature superconductivity^[4][5] and the understanding of heavy fermion compounds.^[6]

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