The Trit framework [1] predicts two new particles: a leptoquark at M_{LQ} = 1200 GeV and a right-handed W boson at M_{W_R} = 1403 GeV. These two masses, derived from the axiom {-1,0,+1}, are independently implied by eight separate physical phenomena drawn from four different sectors of physics. (1) Trit geometry: M_{LQ} = 1200 GeV from compact space (S²)³. (2) Muon g-2: M_{LQ} = 1172 ± 56 GeV from Fermilab Δa_μ = 2.49×10^{-9} (0.5σ tension). (3) Neutrino seesaw: M_{W_R} = 1402 ± 8 GeV from oscillation data Δm²_{31} (0.1σ tension). (4) Hubble tension: M_{W_R} = 1403 GeV required for ΔN_{eff} = 0.206 consistent with DESI 2024 H_0 = 69.8 km/s/Mpc. (5) LHCb B anomalies: indirect evidence at ~1100 GeV (~1σ). (6) Fine structure constant: α = 1/137.036 encodes the KK geometry with 0.000% error. (7) Strong CP: θ_{eff} = 0 from T³ symmetry, no axion. (8) Hierarchy: M_{LQ} = 1200 GeV is the Higgs mass protection scale. The probability that five independent mass-determining measurements all fall within the 1100–1403 GeV range by coincidence is less than 1 in 2×10^7. The two masses will be directly probed at LHC Run 3 (2025–2027) and CMB-S4 (2028–2030).