Gravitational Light Deflection with SKA-VLBI and Its Application to Precision Tests of General Relativity

Abstract

Experimental test of general relativity remains an ongoing endeavour. Radio astrometry provides a vital tool for precisely measuring the light deflection caused by the Sun, testing general relativity, and discriminating between gravitational theories. The best accuracy for the post-Newtonian relativistic parameter, γ, achieved with very long baseline interferometry is 9 × 10-5. With 300-sec integration, SKA-VLBI can achieve a sensitivity of 15 μJy at 15 GHz over a bandwidth of 0.256 GHz. This enables detection of 36 extragalactic radio sources per square degree with flux densities of 1.5 mJy, and potentially detecting in-beam radio sources. Single-epoch SKA-VLBI observations may achieve an astrometric precision of 2 μas. Utilising the Sun as a gravitational lens, 10-epoch positional tracking of extragalactic sources could improve γ accuracy to 10-7. Even with Jupiter as a lens, SKA-VLBI can measure γ to 10-4. Critically, it may conduct the first measurement of quadrupolar deflection of light caused by Jupiter, determining the physical oblateness of Jupiter, J2, J, to within 10-3. These advances are expected to rigorously test and improve gravitational theories or high-order parameterized post-Newtonian formalisms, while laying the foundations for (sub)μas astrometry.