An Indirect Gravity-Microwave Interaction 

   A Deflection at Solar Plasma Limb at Lowest Impact Parameter

Overview of the indirect gravity-microwave-interaction at minimum impact parameter
Findings show that the rays of star light are lensed primarily in the plasma rim of the sun and hardly in the plasma-free vacuum space above the solar plasma rim. The thin plasma atmosphere of the sun appears to represent an indirect interaction involving an interfering plasma medium between the gravitational field of the sun and the rays of star light. Since the light bending rule of General Relativity is essentially a 1/R effect, modern technical means should permit an easily detectable light bending effect of at least 1/2 of 1.75 arcsec, 1/3 of 1.75 arcsec, ..., 1/n of 1.75 arcsec at multiple impact parameters of 2R, 3R, ..., nR, respectively. This assumes the gravitational light bending rule of General Relativity is valid in all space, the plasma-free empty vacuum space as well as the plasma atmosphere of the sun. The same light bending equation obtained by General Relativity was derived from an energy conservation assumption that an electromagnetic wave will propagate along a minimum-energy-path or a least-time path in a plasma atmosphere exposed to the gravitational gradient field of the sun. The derived equation, the same as that of General Relativity, does not contain the frequency of the deflected wave. The minimum-energy-path was found to be totally independent of the frequency of the gravitationally deflected wave. The gravitational deflection of microwaves at the plasma atmosphere of the sun was observed by a large number of researchers who used very-long-baseline-interferome ter (VLBI) techniques on extra galactic radio pulsar sources. The microwaves emitted from the pulsar sources were observed to be deflected at precisely the angle of 1.75 arcsec, confirming that the deflected microwaves occurred at low impact parameters corresponding to the thin plasma limb of the sun. The researchers, Lebach et al. obtained the results of 0.9998+/-0.0008 times 1.75 arcsec for the observed gravitational deflection of microwaves at the solar limb. It is interesting to note that in the literature, VLBI measurements have consistently recorded gravitational deflections of microwaves at the angle of 1.75 arcsec since 1972 with increasing precisions. The gravitational deflections of microwaves from the pulsar and quasar sources have occurred at impact parameters corresponding to the plasma limb of the sun at precisely the angle of 1.75 arcsec. Microwave deflections occurring at angles less than 1.75 arcsec and at higher impact parameters are yet to be observed. Gravitational deflections of microwaves taking place at higher impact parameters will have resulted in smaller angles, say at a deflection of the angle of 0.85 arcsec at the impact parameter 2R or solar radii, a deflection angle of 1/3 of 1.75 arcsec at the impact parameter 3R etc., etc. Gravitational deflections in the microwave frequencies deviate severely from the predicted 1/R effect of General Relativity for high impact parameters greater than that of the solar radius. If the gravitational light bending effect occurred in plasma-free deep vacuum space, according to the predictions of General Relativity, the star filled skies should be filled with images of the Einstein rings. Of course, this assumes the validity of the gravitational light bending rule of General Relativity and that it also applies directly to the empty vacuum space free of plasma atmospheres as well as to the plasma atmospheres of the stars. The burning question is: Where are the Einstein rings? The answer to this question may be a direct consequence of the mean astronomical distances between the stars, forcing the impact parameters of a theoretically bent light ray to lie well above the plasma limb of the gravitating stellar mass. This argument is supported by a clear lack of observational evidence for the presence of Einstein rings or gravitational light bending effects in the star-filled skies as is predicted by the gravitational light bending rule of General Relativity. The astrophysical observational evidence clearly support the fact that the limited Plasma Focal Length of our Sun. ca. 565 AU's, and the sun-like stars, given the mean astronomical distances separating the stars in our observational space, renders the observation of Einstein Rings in our star-filled skies as being totally denied; a direct violation of the light bending rule of General Relativity.  Moreover, events taking place at the center of our galaxy, a region known as Sagittarius A*, thought to contain a super massive black hole, should have revealed observational evidence for gravitational lensing. Nevertheless, a clear lack of evidence for gravitational lensing is revealed in the time resolved images of the rapidly moving stellar objects orbiting about Sagittarius A*. 

Keywords: black hole, gravitational lensing, galactic core, Gauss law, optical reciprocity, plasma focal length

Keywords: black hole, gravitational lensing, galactic core, Gauss law, optical reciprocity, plasma focal length