Hyperbolic form factors for Yukawa interactions, and applications to the Earth

Abstract

We define the hyperbolic form factor of a density distribution as its bilateral Laplace transform, related by duality or analytic continuation to its form factor. For a sphere it is given by (x = kR) = k. r= kr /kr , expanded as Σ x2n(2n+1)! r2nR2n , and similarly for the form factor kr/kr. It is also obtained from the bilateral Laplace transform of 2π r\,(|r|), and enters in the determination of the outside Yukawa potential induced by a new charge for a mediator of mass m=k=1/λ. (x) may be expressed as 3x3\,(x x - x)\ (x)/0, where (x) is an effective density decreasing, for d/dr<0, from the average 0 at small x, down to (R). An inversion formula allows one to recover (r) from an analytic continuation of (x), as (r) =0\,(2R/3π r)∫(ix) (xrR)\,x\,dx. (x) for the Earth is essential to determine limits on a new force, as tested by MICROSCOPE, depending on the density distribution within the Earth. Quite remarkably, much simplified density profiles, such as = 0\ 2R/3r or = 0\, (54-rR+ R3r), provide analytic expressions of (x) and (x) giving almost the same values as in a 5-shell model. \,(x)=(x2/x2)2 is valid to within 1\,\% up to x=4. \,(x)= [7x2 x-24 x+9x x -4x2+24]/(4x4) is valid to within 1 % for λ > 100 km (or m< 2× 10-12 eV/c2). For m=10-12 eV/c2 the coupling limits are increased by 34 as compared to a massless mediator, to |gB-L|< 3.6 × 10-24 and |gB|<2.6× 10-23 for a spin-1 mediator, with slightly different limits in the spin-0 case.

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