# Deceleration of high-velocity interstellar photon sails into bound   orbits at $\alpha$ Centauri

**Authors:** Ren\'e Heller (1), Michael Hippke (2) ((1) Max Planck Institute for, Solar System Research, G\"ottingen (GER), (2) Neukirchen-Vluyn (GER))

arXiv: 1701.08803 · 2017-02-01

## TL;DR

This paper demonstrates how stellar photon pressures and gravity assists can decelerate high-velocity interstellar solar sails at Alpha Centauri, enabling orbit insertion and multi-system visits within a feasible timeframe.

## Contribution

It introduces a method combining stellar photon pressures and gravity assists to decelerate interstellar sails, allowing orbit insertion at Alpha Centauri without onboard propellant.

## Key findings

- Maximum injection speed at Alpha Centauri A is about 13,800 km/s.
- Travel time from Earth to Alpha Centauri A is approximately 95 years.
- A 10-gram payload requires a sail about 316 meters in size.

## Abstract

At a distance of about 4.22 lightyears, it would take about 100,000 years for humans to visit our closest stellar neighbor Proxima Centauri using modern chemical thrusters. New technologies are now being developed that involve high-power lasers firing at 1 gram solar sails in near-Earth orbits, accelerating them to 20% the speed of light (c) within minutes. Although such an interstellar probe could reach Proxima 20 years after launch, without propellant to slow it down it would traverse the system within hours. Here we demonstrate how the stellar photon pressures of the stellar triple $\alpha$ Cen A, B, and C (Proxima) can be used together with gravity assists to decelerate incoming solar sails from Earth. The maximum injection speed at $\alpha$ Cen A to park a sail with a mass-to-surface ratio ($\sigma$) similar to graphene (7.6e-4 gram/m$^{-2}$) in orbit around Proxima is about 13,800 km/s (4.6% c), implying travel times from Earth to $\alpha$ Cen A and B of about 95 years and another 46 years (with a residual velocity of 1280 km/s) to Proxima. The size of such a low-$\sigma$ sail required to carry a payload of 10 grams is about 10$^5$ m$^2$ = (316 m)$^2$. Such a sail could use solar photons instead of an expensive laser system to gain interstellar velocities at departure. Photogravitational assists allow visits of three stellar systems and an Earth-sized potentially habitable planet in one shot, promising extremely high scientific yields.

## Full text

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## Figures

12 figures with captions in the complete paper: https://tomesphere.com/paper/1701.08803/full.md

## References

30 references — full list in the complete paper: https://tomesphere.com/paper/1701.08803/full.md

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Source: https://tomesphere.com/paper/1701.08803