3I/ATLAS (C/2025 N1) — Outbound Baryonic-Matter Prediction Record III (2025-11-23 to 2026-06-01)

This dataset presents the <b>Outbound Baryonic-Matter Prediction Record III</b> for the interstellar object <b>3I/ATLAS (C/2025 N1)</b>, covering the period from <b>2025-11-23 to 2026-06-01</b> as the object travels away from the Sun after perihelion. Using JPL Horizons as the reference gravitational ephemeris, this work provides a fully pre-registered series of predicted astrometric and kinematic deviations (ΔRA, ΔDec, Δv) derived from the <b>Konkle Baryonic-Matter Physics Framework</b>.Building on the author’s earlier inbound and perihelion studies (Figshare DOIs: 29936516, 30335635, 30510980, 30511304, 30546008, 30556721, 30661226), this Record III expands the analysis into the outbound phase, identifying <b>four discrete Baryonic-Matter corridor crossings</b> where measurable departures from the JPL gravity-plus-outgassing model are expected. These include:<b>Solar BM Relaxation</b> following perihelion (late November 2025)<b>Earth-aligned BM corridor</b> near closest approach (2025-12-19)<b>Outbound angle-shift corridor</b> as 3I/ATLAS exits the inner solar compression well (January 2026)<b>Jovian BM compression layer crossing</b> near Jupiter’s closest approach (2026-03-16), predicted to generate the strongest measurable deviationThe dataset provides <b>testable BM predictions</b>, including angular shifts of <b>0.2–0.5 arcsec</b>, velocity deviations of <b>~1 m/s</b>, a forecasted widening of the Earth-distance on 2025-12-19 by <b>0.001–0.005 AU</b>, and a projected <b>10,000-km positional offset</b> during the Jovian corridor event.All predictions are presented prior to observation and are not tuned to residuals. The accompanying table lists the JPL-based reference distances and approximate velocities, alongside the Baryonic-Matter deviation forecasts and their corresponding field-layer classifications.This record forms part of the author’s larger Baryonic-Matter Physics initiative, complementing the upcoming <b>four-volume Baryonic-Matter Physics Quartet</b> and supported by two books currently in print: <b>The Fall of Shadows</b> and <b>Structure at All Scales</b>. It is intended as a transparent scientific benchmark for evaluating deterministic Baryonic-Matter theory against traditional gravitational modeling as new astrometric reductions become available.