Equivalence Principle Tests and New Long-Range Forces
Abstract
We discuss the possible existence of new long-range forces mediated by spin-1 or spin-0 particles. They would add their effects to those of gravity, and could lead to apparent violations of the Equivalence Principle. Informations on the (vector and axial) couplings of a new spin-1 U boson may be obtained from spontaneously broken gauge invariance. The charge associated with the vector coupling may be expressed as a linear combination of B and L. If the new force has a finite range lambda, its intensity turns out to be proportional to 1/(lambda2 F2), F being the extra U(1) symmetry-breaking scale. Quite surprisingly, particle physics experiments can provide constraints on such a force, even if the corresponding gauge coupling is extremely small (<< 10-19 !). An "equivalence theorem" shows that a very light spin-1 U boson with non-vanishing axial couplings does not in general decouple even when its gauge coupling vanishes, but behaves as a quasimassless pseudoscalar. (This equivalence theorem is similar to the one of supersymmetry/supergravity theories, according to which a very light spin-3/2 gravitino might get detectable as a quasi massless spin-1/2 goldstino, despite the extreme smallness of Newton's gravitational constant GN.) Searches for the radiative production of such U bosons in psi and upsilon decays restrict the extra U(1) symmetry-breaking scale F to be larger than the electroweak scale, providing constraints on the intensity of the corresponding new force.
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