Light Deflection under the Gravitational Field of Jupiter -- Testing General Relativity

TL;DR

This study used VLBA observations of extragalactic sources near Jupiter to measure light deflection, testing general relativity by estimating the PPN parameter gamma with high precision.

Contribution

First precise VLBA measurements of light deflection by Jupiter to constrain the relativistic parameter gamma, improving tests of general relativity in the solar system.

Findings

Measured gamma as 0.984 ± 0.037, consistent with general relativity.

Achieved positional accuracy of about 20 microarcseconds in right ascension.

Demonstrated VLBA's capability for high-precision gravitational lensing measurements.

Abstract

We measured the relative positions between two pairs of compact extragalactic sources (CESs), J1925-2219 \& J1923-2104 (C1--C2) and J1925-2219 \& J1928-2035 (C1--C3) on 2020 October 23--25 and 2021 February 5 (totaling four epochs), respectively, using the Very Long Baseline Array (VLBA) at 15 GHz. Accounting for the deflection angle dominated by Jupiter, as well as the contributions from the Sun, planets other than Earth, the Moon and Ganymede (the most massive of the solar system's moons), our theoretical calculations predict that the dynamical ranges of the relative positions across four epochs in R.A. of the C1--C2 pair and C1--C3 pair are 841.2 and 1127.9 $\mu$as, respectively. The formal accuracy in R.A. is about 20 $\mu$as, but the error in Decl. is poor. The measured standard deviations of the relative positions across the four epochs are 51.0 and 29.7 $\mu$as in R.A. for C1--C2 and C1--C3, respectively. These values indicate that the accuracy of the post-Newtonian relativistic parameter, $\gamma$, is $\sim 0.061$ for C1--C2 and $\sim 0.026$ for C1--C3. Combining the two CES pairs, the measured value of $\gamma$ is $0.984 \pm 0.037$, which is comparable to the latest published results for Jupiter as a gravitational lens reported by Fomalont \& Kopeikin, i.e., $1.01 \pm 0.03$.