plasma-expert/exercises/03-spark-physics/phys-ex-comprehensive.yaml

id: phys-ex-comprehensive
type: design
difficulty: hard
points: 100
related_lesson: phys-09
question: |
  COMPREHENSIVE SPARK PHYSICS DESIGN CHALLENGE

  Design a QCW coil from scratch to achieve 3.5 m sparks.

  Given constraints:
  - Budget allows C_primary up to 1.0 μF
  - V_primary limited to 600 V (safety)
  - Topload options: 20 cm toroid (C_top ≈ 25 pF) or 35 cm toroid (C_top ≈ 45 pF)
  - Target ramp time: 10-15 ms
  - Sea level operation (E_propagation = 0.6 MV/m)

  Complete the following analysis:

  1. Energy calculation:
     - Choose ε for QCW mode
     - Calculate total energy required for 3.5 m
     - Verify achievable with C_primary and V_primary

  2. Voltage requirement:
     - Estimate C_mut for each topload (use C_mut ≈ 0.7 × C_top)
     - Calculate C_sh for 3.5 m spark
     - For each topload, calculate V_topload needed for E_tip = 0.7 MV/m at 3.5 m (κ = 3.0)
     - Include capacitive division effects

  3. Power analysis:
     - For T_ramp = 12 ms, calculate required average power
     - Estimate peak power (assume 1.5× average for QCW)
     - Check if reasonable for DRSSTC primary

  4. Thermal verification:
     - Estimate leader diameter (2-4 mm typical)
     - Calculate thermal time constant
     - Verify ramp time << thermal time

  5. Final recommendation:
     - Which topload should be used?
     - Is 3.5 m target achievable?
     - If not, what would you change?  

hints:
  - "Use ε ≈ 10-12 J/m for QCW mode"
  - "Remember capacitive divider: V_tip = V_topload × C_mut/(C_mut + C_sh)"
  - "E_tip = κ × V_tip / L must exceed E_propagation"
  - "Thermal time: τ = d²/(4α) with α = 2×10⁻⁵ m²/s"

solution:
  energy_calculation:
    chosen_epsilon: "11 J/m (typical QCW)"
    total_energy: "E = ε × L = 11 × 3.5 = 38.5 J"
    primary_check: "E_primary = 0.5 × C × V² = 0.5 × 1.0×10⁻⁶ × 600² = 180 J"
    verdict: "38.5 J << 180 J available ✓ Energy adequate"

  voltage_requirement:
    small_toroid:
      C_top: "25 pF"
      C_mut_est: "17.5 pF"
      C_sh: "23.1 pF (6.6 pF/m × 3.5 m)"
      V_tip_needed: "V_tip = E_prop × L / κ = 0.7×10⁶ × 3.5 / 3.0 = 817 kV"
      V_topload_needed: "V_top = V_tip × (C_mut + C_sh) / C_mut = 817 × 40.6/17.5 = 1,896 kV"
      verdict: "Unrealistic voltage required ✗"

    large_toroid:
      C_top: "45 pF"
      C_mut_est: "31.5 pF"
      C_sh: "23.1 pF"
      V_tip_needed: "817 kV (same)"
      V_topload_needed: "V_top = 817 × 54.6/31.5 = 1,416 kV"
      verdict: "Still very high, challenging ✗"

  power_analysis:
    ramp_time: "12 ms"
    avg_power: "P = E/T = 38.5 J / 0.012 s = 3.2 kW"
    peak_power: "~5 kW (1.5× average)"
    verdict: "Power requirement is modest ✓"

  thermal_verification:
    leader_diameter: "3 mm (estimate)"
    thermal_constant: "τ = (0.003)² / (4 × 2×10⁻⁵) = 113 ms"
    comparison: "T_ramp (12 ms) < τ (113 ms), ratio = 0.11"
    verdict: "Leader stays hot during ramp ✓ QCW condition satisfied"

  final_recommendation: |
    Neither topload can achieve 3.5 m with realistic voltages due to capacitive
    division. To achieve 3.5 m:

    Option 1: Accept shorter sparks (~2-2.5 m achievable with large toroid)
    Option 2: Increase primary voltage capability (beyond 600 V safety limit)
    Option 3: Use active voltage ramping to counteract division
    Option 4: Add intermediate electrode to reduce effective spark length

    Recommended: Use 35 cm toroid, target 2.5 m realistic goal, accept that
    voltage limitation dominates. Energy and power are adequate, but voltage
    limit prevents reaching 3.5 m target.    

explanation: |
  This comprehensive design challenge demonstrates the interplay between energy,
  voltage, and power limitations. The analysis reveals that voltage (electric field
  requirement) is the primary constraint, not energy or power. Capacitive division
  significantly increases the required topload voltage. The larger toroid helps but
  doesn't fully solve the problem. This is typical for Tesla coils - voltage-limited
  rather than power-limited. Realistic design must balance these constraints.  

related_concepts: ["design-integration", "voltage-vs-power-limits", "capacitive-divider", "QCW-optimization"]