Electrophilic scalar hair from rotating magnetized stars and effects of cosmic neutrino background

Ultralight electrophilic scalar field can mediate a long-range force or radiate from a pulsar or a magnetar if the scalar field has a coupling with the Goldreich-Julian charge density or the net electron charge density of the star. The interaction of the electron with the long-range scalar profile results in a spatial variation of the electron mass. A scalar induced magnetic field is created due to such interaction. The mass of the scalar in such cases is constrained by the radius of the star. The scalar field can also radiate from a binary system or an isolated star if the mass of the scalar is less than the orbital frequency and the spin frequency respectively. The electrophilic scalar radiation can contribute to the orbital period loss of binary systems and pulsar spin-down. Comparing with existing and projected experimental sensitivities, we obtain constraints on scalar coupling with ultralight mass. Some of these bounds are stronger than the existing fifth force constraints. The constraints on the scalar coupling can be significantly screened if the scalar has a coupling with the ubiquitous cosmic neutrino background. Improvements in experimental sensitivity and observations of compact objects with stronger magnetic fields and higher angular velocities could further refine these bounds.