PEARL-GATE V62c

MHD Field Reversal Braking · Stellar Wind · RK4

Time Integrator 1× (Real)

Physics-Dictated Regimes

1. BOOTSTRAP (10kW)

2. TE PULSED (V_acc Climbing)

3. HADRONIC THRESHOLD (ECM≥3.75GeV)

4. HADRONIC CW (P_beam≥1.5MW)

5. ISM AUGMENTED (v ≥ 0.03c)

6. NEP MODE (Fuel=0)

7. END OF LIFE (Kilopower Dead)

8. MHD DECEL (Field Reversal)

Engineering Configuration

Tamper Ratio (μ)

Fuel Mass (kg)

Destination

Target Distance4.24 ly

Global Kinematics (RK4)

Velocity0.0000 %c

Distance0.000 AU

Proper Time (τ)0Y 0D

Earth Time (t)0Y 0D

Dimensionless Groups

Π₁ = Q_tot / P_beam0.00

Π₂ = Q_tot / (ṁc²)0.00

Π₃ = Q_out / Q_in0.00

Π₄ = P_TE / Q_tot0.00

Π₅ = μ (tamper)1.00

Π₆ = ṁ_ISM / ṁ_tot0.00

MHD Field Reversal Braking

ModeINACTIVE

Dist to target—

Medium ρISM 2e-23

ṁ captured0

F_brake0 N

γ_in / γ_out— / —

Est. stop dist—

LTD Pulse BoostSTANDBY

A_eff multiplier1.0×

LTD cycles (brake)—

Energy Conservation (RK4)

Beam In0 J

Nuclear Out0 J

Ship KE0 J

Exhaust KE0 J

Thermal (cumul)0 J

Radiated0 J

η (KE/Nuc)0%

ν/γ Escape0 J

RK4 err—

Multi-Species Plume WAKEFIELD: DECOUPLED

FF (~4%c)0 N

ṁ_FF0

Fusion (~10%c)0 N

ṁ_Fus0

Pion (~99%c)0 N

ṁ_π0

Tamper (~4%c)0 N

ṁ_abl0

Total Thrust 0 N

Consumables

Main Target (U/LiD)15000 kg

Ready0 kg/s

LiH Injectant1.00e-6 kg

Available0

Laser Crystal100.0%

Nominal0

LTD Capacitor100.0%

Active0

Kilopower Core50.00 YRS

Rated: 10kW @ 15Y, then degrades

Standby0

Efficiency100%

LIA & Reactor Core

Target Temp293.0 K

TE Power0 kW

Beam Power10.0 kW

LIA Potential1.00 GV

ECM1.37 GeV

🔄 MHD Field Reversal Braking — Physics

Deceleration uses magnetic field geometry modulation (cymatics-like reshaping), not physical rotation. The ship orientation never changes. The funnel's magnetic topology reverses to redirect captured medium forward instead of aft.

Momentum Transfer (Relativistic)

Medium (ISM or stellar wind) enters funnel at ship velocity: p_in = ṁ·γ_ship·v_ship
Field redirects medium forward at v_exit: p_out = ṁ·γ_out·v_exit
Braking force: F_brake = ṁ·(γ_in·v_in + γ_out·v_out)
This is ~2× the force of simply catching the ISM (inelastic capture gives only F = ṁ·γ·v), because the redirected momentum adds to the captured momentum.

With TE/Kilopower Energy Addition

Energy per unit mass of redirected medium: (γ_out − 1)c² = (γ_in − 1)c² + P_avail/ṁ
So: γ_out = γ_in + P_avail/(ṁ·c²), and v_out = c·√(1 − 1/γ_out²)
Adding energy increases v_out > v_in, amplifying the braking force beyond passive reflection.

Stellar Wind Enhancement

ISM density: ρ_ISM ≈ 2×10⁻²³ kg/m³ (Local Bubble)
Stellar wind at 1 AU from target: ρ_wind ≈ 8×10⁻²¹ kg/m³ (Sun-like) — 400× denser
Wind density scales as 1/r²: ρ(r) = ρ_1AU / r²
Astrosphere boundary: ~500 AU from star. Inside this, stellar wind dominates ISM.
At 10 AU: ρ ≈ 8×10⁻²³ (8× ISM). At 1 AU: ρ ≈ 8×10⁻²¹ (400× ISM). At 0.1 AU: ρ ≈ 8×10⁻¹⁹ (40,000× ISM).
Braking effectiveness increases dramatically on final approach.

⚠️ Braking Simplifications

Stellar wind assumed radially symmetric and steady-state.
Braking trigger is heuristic (estimated stopping distance ≤ remaining distance).
No trajectory optimisation — constant braking once engaged.
Magnetic field efficiency for momentum reversal assumed 100%.