New Explicit Lorentzian Einstein-Weyl Structures in 3-Dimensions

Abstract

On a 3D manifold, a Weyl geometry consists of pairs (g, A) = (metric, 1-form) modulo gauge g = e2 g, A = A + d. In 1943, Cartan showed that every solution to the Einstein-Weyl equations R(μ) - 13 R gμ = 0 comes from an appropriate 3D leaf space quotient of a 7D connection bundle associated with a 3 rd order ODE y''' = H(x,y,y',y'') modulo point transformations, provided 2 among 3 primary point invariants vanish W\"unschmann(H) 0 Cartan(H). We find that point equivalence of a single PDE zy = F(x,y,z,zx) with para-CR integrability DF := Fx + zx Fz 0 leads to a completely similar 7D Cartan bundle and connection. Then magically, the (complicated) equation W\"unschmann(H) 0 becomes 0(F):=9Fpp2Fppppp-45FppFpppFpppp+40Fppp3, p:=zx, whose solutions are just conics in the \p, F\-plane. As an ansatz, we take F(x,y,z,p):= α(y)(z-xp)2+β(y)(z-xp)p+γ(y)(z-xp) +δ(y)p2+(y)p+ζ(y)λ(y)(z-xp)+μ(y) p+(y), with 9 arbitrary functions α, …, of y. This F satisfies DF 0 Monge(F), and we show that the condition Cartan(H) 0 passes to a certain K(F) 0 which holds for any choice of α(y), …, (y). Descending to the leaf space quotient, we gain ∞-dimensional functionally parametrized and explicit families of Einstein-Weyl structures [ (g, A) ] in 3D. These structures are nontrivial in the sense that dA 0 and Cotton([g]) 0.