We present two novel methods, tested by LISA Pathfinder, to measure the gravitational constant G for the first time in space. Experiment 1 uses electrostatic suspension forces to measure a change in acceleration of a test mass due to a displaced source mass. Experiment 2 measures a change in relative acceleration between two test masses due to a slowly varying fuel tank mass. Experiment 1 gave a value of G=6.71±0.42(×10−11)m3s−2kg−1 and experiment 2 gave 6.15±0.35(×10−11)m3s−2kg−1, both consistent with each other to 1σ and with the CODATA 2014 recommended value of 6.67408±0.00031(×10−11) m3s−2kg−1 to 2σ. We outline several ideas to improve the results for a future experiment, and we suggest that a measurement in space would isolate many terrestrial issues that could be responsible for the inconsistencies between recent measurements.
Novel methods to measure the gravitational constant in space
Cavalleri, A.;
2019-01-01
Abstract
We present two novel methods, tested by LISA Pathfinder, to measure the gravitational constant G for the first time in space. Experiment 1 uses electrostatic suspension forces to measure a change in acceleration of a test mass due to a displaced source mass. Experiment 2 measures a change in relative acceleration between two test masses due to a slowly varying fuel tank mass. Experiment 1 gave a value of G=6.71±0.42(×10−11)m3s−2kg−1 and experiment 2 gave 6.15±0.35(×10−11)m3s−2kg−1, both consistent with each other to 1σ and with the CODATA 2014 recommended value of 6.67408±0.00031(×10−11) m3s−2kg−1 to 2σ. We outline several ideas to improve the results for a future experiment, and we suggest that a measurement in space would isolate many terrestrial issues that could be responsible for the inconsistencies between recent measurements.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
