Topology-Controlled Inter-Horizon Correlations in Thermofield Double States: 100-Qubit Experimental Validation with Pre-Registered Controls and Calibration-Drift Characterization

We report systematic experimental observation of coherent, topology-dependent inter-horizon correlations in thermofield double (TFD) states implemented on IBM quantum processors. Using a 100-qubit ladder geometry mapped onto the heavy-hex topology of ibmfez (156 qubits, Heron r2 architecture), we demonstrate signal ratios Rfit spanning 1. 2–202. 7 across runs/seeds, with best single-seed Rfit = 23. 93 (Run #11) and record multi-seed median Rfit = 102. 7 (Run #2, 5 seeds, range 63. 5–202. 7), validated by pre-registered GO/NO-GO criteria across 14 experimental runs spanning January 24-30, 2026. Our experimental framework incorporates two rigorous anti-artifact controls (see Fig. 6-7): (1) SCRAMBLE control applies identical circuit depth with incorrect topology, destroying the signal (reduction factor > 10×) ; (2) ECHO control (Loschmidt reversal) applies the coupling layer twice, annihilating coherent contributions (reduction factor 8. 6-50. 5×, consistent with expected finite-size echo saturation for N~50 effective subsystems (see Gorin et al. 14 for saturation plateau theory) ). Both controls maintain > 95% local fringe retention, confirming they do not trivially destroy coherence. A critical discovery emerged from our January 30, 2026 validation campaign (see Fig. 5): quantum processor calibration drift can cause signal collapse within less than one hour on hardware with identical offline calibration snapshots. Runs #11-#12 achieved Rfit = 23. 93 and 18. 4 respectively (GO-1 PASS, GO-3 PASS), while Run #13 executed only 53 minutes later on the same backend collapsed to Rfit = 1. 20 (GO-1 FAIL). This finding establishes that offline Health Scores do not reliably predict experimental success, and defines an operational envelope requiring Health > 80% (Grade B or better) for empirically associated with high-probability signal stability. The observed second-harmonic (2ω) dominance in the phase-dependent signal (A₂ω/A₁ω > 40×, R² > 0. 99, see Fig. 9) is consistent with theoretical predictions for bilinear left-right correlations. A stride sweep (s = 2-5, see Fig. 4) reveals a signal-coherence trade-off, with s = 3 identified as optimal. Total quantum processor time across all 14 runs: approximately 45 minutes. These results establish a validated, falsifiable experimental framework for probing analog quantum gravity signatures on NISQ hardware, with explicit calibration-conditional bounds. The methodology may provide a validated framework applicable to analog Hawking radiation platforms where topology-controlled correlations play a central role (see Section 5. 4). Note: Results demonstrated primarily on IBM ibmfez; multi-device validation on additional backends is recommended to establish cross-platform generalizability.