Thrust measurements and evaluation of asymmetric infrared laser resonators for space propulsion

Since modern propulsion systems are insufficient for large-scale space exploration, a breakthrough in propulsion physics is required. Amongst different concepts, the EMDrive is a proposed device claiming to be more efficient in converting energy into propulsive forces than classical photon momentum...

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Veröffentlicht in:	CEAS space journal 2022, Vol.14 (1), p.45-62
Hauptverfasser:	Neunzig, O., Weikert, M., Tajmar, M.
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Sprache:	eng
Schlagworte:	Aerospace Technology and Astronautics Asymmetry Cavity resonators Engineering Fiber optics Inertia Infrared lasers Lasers Microwaves Optical resonators Original Paper Photons Propulsion systems Radiation pressure Space exploration Thrust
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creator	Neunzig, O. Weikert, M. Tajmar, M.
description	Since modern propulsion systems are insufficient for large-scale space exploration, a breakthrough in propulsion physics is required. Amongst different concepts, the EMDrive is a proposed device claiming to be more efficient in converting energy into propulsive forces than classical photon momentum exchange. It is based on a microwave resonator inside a tapered cavity. Recently, Taylor suggested using a laser instead of microwaves to boost thrust by many orders of magnitude due to the higher quality factor of optical resonators. His analysis was based on the theory of quantised inertia by McCulloch, who predicted that an asymmetry in mass surrounding the device and/or geometry is responsible for EMDrive-like forces. We put this concept to the test in a number of different configurations using various asymmetrical laser resonators, reflective cavities of different materials and size as well as fiber-optic loops, which were symmetrically and asymmetrically shaped. A dedicated high precision thrust balance was developed to test all these concepts with a sensitivity better than pure photon thrust, which is the force equivalent to the radiation pressure of a laser for the same power that is used to operate each individual devices. In summary, all devices showed no net thrust within our resolution at the Nanonewton range, meaning that any anomalous thrust must be below state-of-the-art propellantless propulsion. This puts strong limits on all proposed theories like quantised inertia by at least 4 orders of magnitude for the laboratory-scale geometries and power levels used with worst case assumptions for the theoretical predictions.
doi_str_mv	10.1007/s12567-021-00366-4
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subjects	Aerospace Technology and Astronautics Asymmetry Cavity resonators Engineering Fiber optics Inertia Infrared lasers Lasers Microwaves Optical resonators Original Paper Photons Propulsion systems Radiation pressure Space exploration Thrust
title	Thrust measurements and evaluation of asymmetric infrared laser resonators for space propulsion
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