What question did this study set out to answer?

The memo aims to investigate if time is influenced by a scalar field in addition to general relativity's proper time.

March 13, 2026Open Access

Spacecraft Clock Memo

Key Points

The memo aims to investigate if time is influenced by a scalar field in addition to general relativity's proper time.
Proposes an experiment using spacecraft clocks to detect oscillations at twice the scalar field's Compton frequency.
Compares spacecraft clock signals with orbital timings to identify non-harmonic narrowband signals.
Calculates experiment sensitivity based on the mass of the scalar field using realistic colored noise.
Sensitivity is strongly dependent on the scalar field mass.
At low masses (below ~10⁻²¹ eV), existing GNSS ground clocks perform better due to flicker noise.
In the mid mass range (~10⁻²¹ to 10⁻¹⁸ eV), space optical clocks outperform by 10–1000 times.
For high masses (above ~10⁻¹⁸ eV), space nuclear clocks show performance improvements by up to 15,600 times.

Abstract

This is a technical memo that proposes a specific experiment to test whether time is mediated by a scalar field rather than by GR proper time alone. The core idea: If a massive scalar field couples disformally to the matter metric, every clock should show a tiny oscillation at twice the field's Compton frequency (the "2f signal"). GR predicts no such thing — after subtracting orbital effects, the residual should be zero. So you compare a clock to its orbit and look for a narrowband line that isn't at any orbital harmonic. What the memo actually computes: The sensitivity of this experiment as a function of the scalar field mass, using realistic colored noise (not idealized white noise). The key finding is that sensitivity is strongly mass-dependent: - Low mass (below ~10⁻²¹ eV): Existing GNSS ground clocks are already better — flicker noise kills the spacecraft advantage - Mid mass (~10⁻²¹ to 10⁻¹⁸ eV): Space optical clocks win by 10–1000× - High mass (above ~10⁻¹⁸ eV): Space nuclear clocks (Th-229) win by up to 15,600× The deliverables are four figures: 1. A discovery map showing which experiment covers which mass range 2. A noise budget showing why the crossover happens (colored noise structure) 3. The improvement factor and crossover mass vs observation time 4. A simulated detection at SNR 265 proving the signal separates from GR orbital timing

Spacecraft Clock Memo

Key Points

Abstract

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