# A HERO for general relativity

**Authors:** Lorenzo Iorio

arXiv: 1906.05728 · 2019-07-08

## TL;DR

HERO is a proposed space mission to test post-Newtonian gravity effects around Earth, utilizing a highly elliptical orbit to detect subtle relativistic phenomena and constrain alternative gravity models with high precision.

## Contribution

The paper introduces the HERO mission concept, proposing a novel approach to measure relativistic effects and Earth's gravity parameters using a highly eccentric orbit and advanced data analysis techniques.

## Key findings

- Potential to detect Earth's quadrupole-induced orbital effects.
- High-accuracy tests of Lense-Thirring and Schwarzschild effects.
- Ability to constrain modified gravity models and measure gravitational red-shift.

## Abstract

HERO (Highly Eccentric Relativity Orbiter) is a space-based mission concept aimed to perform several tests of post-Newtonian gravity around the Earth with a preferably drag-free spacecraft moving along a highly elliptical path fixed in its plane undergoing a relatively fast secular precession. We considered two possible scenarios: a fast, 4-hr orbit with high perigee height of $1,047\,\mathrm{km}$, and a slow, 21-hr path with a low perigee height of $642\,\mathrm{km}$. HERO may detect, for the first time, the post-Newtonian orbital effects induced by the mass quadrupole moment $J_2$ of the Earth which affects the semimajor axis $a$ via a secular trend of $\simeq 4-12\,\mathrm{cm\,yr}^{-1}$, depending on the orbital configuration. Recently, the secular decay of the semimajor axis of the passive satellite LARES was measured with an error as little as $0.7\,\mathrm{cm\,yr}^{-1}$. Also the post-Newtonian spin dipole (Lense-Thirring) and mass monopole (Schwarzschild) effects could be tested to a high accuracy depending on the level of compensation of the non-gravitational perturbations. Moreover, the large eccentricity of the orbit would allow to constrain several long-range modified models of gravity and to accurately measure the gravitational red-shift as well. Each of the six Keplerian orbital elements could be individually monitored to extract the $GJ_2/c^2$ signature, or they could be suitably combined in order to disentangle the post-Newtonian effect(s) of interest from the competing mismodeled Newtonian secular precessions induced by the zonal harmonic multipoles $J_\ell$ of the geopotential. In the latter case, the systematic uncertainty due to the current formal errors $\sigma_{J_\ell}$ of a recent global Earth's gravity field model are better than $1\%$ for all the post-Newtonian effects considered, with a peak of $\simeq 10^{-7}$ for the Schwarzschild-like shifts. [Abridged]

## Full text

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## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/1906.05728/full.md

## References

56 references — full list in the complete paper: https://tomesphere.com/paper/1906.05728/full.md

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Source: https://tomesphere.com/paper/1906.05728