Exact Four-Parameter Rotating NS--NS Vacuum in Double Field Theory

Abstract

We construct an exact rotating vacuum of the NS--NS sector, equivalently a Double Field Theory vacuum. The construction applies compact SO(2) S-duality to a rotating Einstein--scalar seed. The solution has four independent parameters \m,j,q,ζ\. To our knowledge, this is the first explicit rotating solution of the pure NS--NS vacuum equations with all three NS--NS fields \g,B,ϕ\ determined analytically, independent dilaton and H-flux charges, and no Maxwell sector. The static limit is obtained by taking the rotation parameter j 0. In this limit the geometry is not the spherical Burgess--Myers--Quevedo solution. Instead, it is an axial Zipoy--Voorhees branch carrying H-flux, so an oblate deformation remains after rotation is switched off. This geometric memory is absent in pure general relativity and in Einstein--Maxwell--dilaton--axion. The two static branches nevertheless share the same =0 parametrized post-Newtonian data \MG,βPPN,γPPN,h\. They give two inequivalent NS--NS geometries at identical monopole charges, with the degeneracy lifted at =2. At the Kerr horizon locus the outer shell is generically singular in curvature. Above the threshold |q|>m2-j2, polar geodesics are repelled outward and the rotation axis becomes regular in curvature at the shell. On that axis the inverse metric gμν stays finite while the lower-index Riemannian metric components diverge, whereas off the axis the inverse metric itself diverges. This axis-local degeneracy may offer a setting for non-Riemannian geometry in Double Field Theory, where gμν is not fundamental and the O(D,D) variables \d,HAB\ remain well defined.