Domain wall fermion

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In lattice field theory, domain wall (DW) fermions are a fermion discretization avoiding the fermion doubling problem.^[1] They are a realisation of Ginsparg–Wilson fermions in the infinite separation limit ${\displaystyle L_s\to \mathrm{\infty }}$ where they become equivalent to overlap fermions.^[2] DW fermions have undergone numerous improvements since Kaplan's original formulation^[1] such as the reinterpretation by Shamir and the generalisation to Möbius DW fermions by Brower, Neff and Orginos.^[3][4]

The original ${\displaystyle d}$-dimensional Euclidean spacetime is lifted into ${\displaystyle d+1}$ dimensions. The additional dimension of length ${\displaystyle L_s}$ has open boundary conditions and the so-called domain walls form its boundaries. The physics is now found to ″live″ on the domain walls and the doublers are located on opposite walls, that is at ${\displaystyle L_s\to \mathrm{\infty }}$ they completely decouple from the system.

Kaplan's (and equivalently Shamir's) DW Dirac operator is defined by two addends

${\displaystyle D_{\text{DW}}(x,s;y,r)=D(x;y){\delta }_{sr}+{\delta }_{xy}{D}_{d+1}(s;r)}$

with

${\displaystyle D_{d+1}(s;r)={\delta }_{sr}-(1-{\delta }_{s,L_s-1})P_{-}{\delta }_{s+1,r}-(1-{\delta }_{s0})P_{+}{\delta }_{s-1,r}+m(P_{-}{\delta }_{s,L_s-1}{\delta }_{0r}+P_{+}{\delta }_{s0}{\delta }_{L_s-1,r})}$

where ${\displaystyle P_{\pm }=(\mathrm{𝟏}\pm {\gamma }_5)/2}$ is the chiral projection operator and ${\displaystyle D}$ is the canonical Dirac operator in ${\displaystyle d}$ dimensions. ${\displaystyle x}$ and ${\displaystyle y}$ are (multi-)indices in the physical space whereas ${\displaystyle s}$ and ${\displaystyle r}$ denote the position in the additional dimension.^[5]

DW fermions do not contradict the Nielsen–Ninomiya theorem because they explicitly violate chiral symmetry (asymptotically obeying the Ginsparg–Wilson equation).

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