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Chiral Anomaly of Kogut-Susskind Fermion in (3+1)-dimensional Hamiltonian formalism

Published 9 Nov 2025 in hep-lat, cond-mat.str-el, and hep-th | (2511.06198v1)

Abstract: We consider Kogut-Susskind fermions (also known as staggered fermions) in a $(3+1)$-dimensional Hamiltonian formalism and examine a chiral transformation and its associated chiral anomaly. The Hamiltonian of the massless Kogut-Susskind fermion has symmetry under the shift transformations in each space direction $S_k \, (k=1,2,3)$, and the product of the three shift transformations in particular (the odd shifts in general) may be regarded as a unitary discrete chiral transformation, modulo two-site translations. The hermitian part of the transformation kernel $\Gamma = i S_1 S_2 S_3$ can define an axial charge as $Q_A = (1/2)\sum_x \chi\dagger(x) \left(\Gamma+\Gamma\dagger \right)\chi(x)$, which is non-onsite, nonquantized, and commutative with the vector charge, analogous to $\tilde{Q}A = (1/2) \sum_n ( \chi\dagger_n \chi{n+1} + \chi\dagger_{n+1} \chi_{n} )$ for the $(1+1)$ dimensional Kogut-Susskind fermion. However, our $Q_A$ cannot be expressed in terms of any quantized charges in a generalized Onsager algebra. Although $Q_A$ does not commute with the fermion Hamiltonian in general when coupled to background link gauge fields, we show that they become commutative for a class of $U(1)$ link configurations carrying nontrivial magnetic and electric fields. We then verify numerically that the vacuum expectation value of $Q_A$ satisfies the anomalous conservation law of axial charge in the continuum two-flavor theory under an adiabatic evolution of the link gauge field.

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