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Tesla Coil Spark Physics - Physical Bounds and Typical Ranges

Reference for validation criteria, physical constraints, and empirical values.

Resistance Bounds

Lumped Model

Physical limits:

R_min ≈ 1 kΩ      (very hot, thick leader plasma)
R_max ≈ 100 MΩ    (cold, thin streamer plasma)

R_actual = clip(R_opt_power, R_min, R_max)

nth-Order Model (Position-Dependent)

Base segments (position = 0):

R_min = 1 kΩ
R_max = 100 kΩ

Tip segments (position = 1):

R_min = 10 kΩ
R_max = 100 MΩ

Interpolated formula:

position = i/(n-1)

R_min[i] = 1 kΩ + (10 kΩ - 1 kΩ) × position
         = 1 kΩ + 9 kΩ × position

R_max[i] = 100 kΩ + (100 MΩ - 100 kΩ) × position
         ≈ 100 kΩ + 99.9 MΩ × position

Typical Total Resistance (by operating mode)

At 200 kHz for 1-3 meter sparks:

Operating Mode	Total R	Characteristics
Burst/Streamer-dominated	50-300 kΩ	Short pulses, thin channels
QCW/Leader-dominated	5-50 kΩ	Long ramps, hot thick channels
Very low frequency (<100 kHz) or very long sparks	1-10 kΩ	Thick leaders, high power

Validation flag: If R_total is significantly outside these ranges for your frequency and length, investigate potential issues.

Capacitance Values

Mutual Capacitance (C_mut)

Typical values:

Spark Length	Typical C_mut	Notes
1 foot (0.3 m)	3-5 pF	Small topload
2 feet (0.6 m)	5-8 pF	Medium topload
3 feet (0.9 m)	7-12 pF	Large topload
5 feet (1.5 m)	10-15 pF	Very large topload

Depends on topload size and geometry

Shunt Capacitance (C_sh)

Empirical rule:

C_sh ≈ 2 pF per foot of spark length

Examples:

Spark Length	Typical C_sh
1 foot (0.3 m)	2 pF
2 feet (0.6 m)	4 pF
3 feet (0.9 m)	6 pF
5 feet (1.5 m)	10 pF
10 feet (3.0 m)	20 pF

Validation: Use this rule to verify FEMM extraction accuracy.

Capacitance Ratio (r)

r = C_mut/C_sh

Typical geometries:

Configuration	r value	φ_Z,min
Large topload, short spark	0.5 - 2.0	-50° to -70°
Medium topload, medium spark	0.3 - 0.8	-48° to -60°
Small topload, long spark	0.1 - 0.4	-43° to -52°

Critical threshold: When r ≥ 0.207, achieving φ_Z = -45° becomes impossible.

Diameter Dependence

Weak logarithmic scaling:

C ∝ 1/ln(h/d)

Where:

h = height above ground
d = channel diameter

Typical change: 2× diameter → ~10-15% change in C

Electric Field Thresholds

Inception Field

Smooth electrode breakdown:

E_inception ≈ 2-3 MV/m  (sea level, standard conditions)

Variations:

Sharp electrodes: 1-2 MV/m (lower threshold)
Very smooth, large radius: 3-4 MV/m (higher threshold)

Propagation Field

Sustained leader growth:

E_propagation ≈ 0.4-1.0 MV/m  (typical range)

Common values:

Conservative estimate: 0.8-1.0 MV/m
Optimistic/ideal conditions: 0.4-0.6 MV/m
Typical use for modeling: 0.6-0.7 MV/m

Tip Enhancement Factor

E_tip = κ × E_average

Typical values:

κ ≈ 2-5 for cylindrical channels
Higher for sharper geometries
Use FEMM to calculate actual enhancement

Altitude and Environmental Effects

Altitude correction (rough approximation):

E(altitude) = E(sea level) × (P/P_0)

where P/P_0 ≈ exp(-h/8500 m)

Examples:

Altitude	Pressure Ratio	Field Scaling
Sea level	1.0	1.0
1500 m (Denver)	~0.83	~0.83
3000 m	~0.69	~0.69

Humidity effects: ±10-20% variation (higher humidity → slightly lower threshold)

Temperature: ±5-10% variation over normal range

Total variability: E_propagation can vary ±20-30% with environmental conditions

Energy per Meter (ε)

By Operating Mode

QCW-style growth:

ε ≈ 5-15 J/m

Characteristics:
- Long ramp times (5-20 ms)
- Leader-dominated channels
- Energy efficiently extends length
- White/orange appearance

High duty cycle DRSSTC:

ε ≈ 20-40 J/m

Characteristics:
- Hybrid streamer/leader formation
- Some thermal accumulation
- Moderate efficiency
- Mixed appearance

Hard-pulsed DRSSTC (burst mode):

ε ≈ 30-100+ J/m  (single-shot)

Characteristics:
- Short pulses, mostly streamers
- Much energy → brightening/branching
- Poor length efficiency
- Purple/blue, highly branched

Calibration Requirements

Essential: Calibrate ε for your specific coil from measurements.

Procedure:

Run coil with known drive power and time
Measure final spark length L
From SPICE, compute E_delivered = ∫P_spark dt
Calculate: ε = E_delivered/L

Expected precision: ±30-50% due to variability in plasma conditions

Thermal Time Constants

Pure Thermal Diffusion

Formula:

τ_thermal = d² / (4α)

where α = k/(ρ_air × c_p) ≈ 2×10⁻⁵ m²/s for air

By diameter:

Diameter	Type	τ_thermal	Observed Persistence
100 μm	Thin streamer	0.1-0.2 ms	~1-5 ms
1 mm	Thick streamer	12-25 ms	~10-50 ms
5 mm	Leader	300-600 ms	seconds
1 cm	Thick leader	1-2 seconds	10+ seconds

Note: Observed persistence is longer than pure thermal diffusion due to:

Buoyancy and convection maintaining hot gas column
Ionization memory (recombination slower than thermal diffusion)
Broadened effective channel diameter

Operating Regime Implications

QCW advantage:

Ramp times 5-20 ms match streamer-to-leader persistence
Channel stays hot throughout growth
Efficient energy coupling

Burst mode:

Pulse spacing > 5 ms → channel cools between pulses
Must re-ionize repeatedly
Less efficient for length

Phase Angles

Impedance Phase (φ_Z)

Typical ranges:

R = R_opt_power typically gives: φ_Z ≈ -55° to -75°

By capacitance ratio:

r = C_mut/C_sh	φ_Z,min	Typical at R_opt
0.1	-42°	-55° to -60°
0.3	-50°	-60° to -65°
0.5	-55°	-62° to -68°
1.0	-65°	-68° to -73°
2.0	-73°	-72° to -76°

Important: The commonly cited "-45°" is often unachievable due to circuit topology.

Admittance Phase (θ_Y)

θ_Y = -φ_Z

Typical ranges: +55° to +75° (positive, capacitive)

Frequency Ranges

Operating Frequencies

Typical Tesla coil operating frequencies:

Coil Type	Frequency Range	Notes
Small DRSSTC	150-400 kHz	Higher frequency, smaller secondary
Medium DRSSTC	100-250 kHz	Most common range
Large DRSSTC	50-150 kHz	Lower frequency, larger secondary
SSTC	100-500 kHz	Wide range possible
QCW	50-200 kHz	Typically lower frequencies

Loaded vs Unloaded

Frequency shift with spark:

Typical shift: 5-20% lower when loaded
Larger sparks → larger shift
Track frequency to loaded pole for accurate measurements

Power Levels and Efficiencies

Typical Power Ranges

By coil size:

Coil Class	Primary Power	Spark Power	Typical η
Small DRSSTC	0.5-2 kW	0.1-0.5 kW	15-30%
Medium DRSSTC	2-5 kW	0.5-1.5 kW	20-35%
Large DRSSTC	5-15 kW	1.5-5 kW	25-40%
QCW	1-10 kW	0.5-4 kW	30-50%

Efficiency components:

Spark power delivery: 15-50%
Secondary losses (heating): 10-30%
Primary circuit losses: 20-40%
Corona and radiation: 5-15%

Power Density

Typical values in spark channel:

P/L ≈ 50-500 W/m  (power per unit length)

Higher for burst mode (bright but short), lower for QCW (efficient leaders).

Geometric Constraints

Minimum Capacitance Bounds

For stable operation:

C_mut + C_sh ≥ 5 pF  (typical minimum for 100+ kHz)

Below this, impedance becomes very high and matching becomes difficult.

Maximum Practical Length

Voltage-limited:

L_max ≈ V_top_peak / E_propagation

Typical: V_top = 300-600 kV → L_max = 3-6 feet at E_prop = 1 MV/m

Power-limited:

L_max ≈ P_available × T / ε

where T is growth time available

Practical limit: Whichever is more restrictive.

Plasma Properties

Conductivity Range

Partially ionized air plasma:

σ ≈ 0.01 - 10 S/m  (wide range depending on temperature and ionization)

Equivalent resistivity:

ρ ≈ 0.1 - 100 Ω·m

Typical for modeling:

Hot leader: ρ ≈ 1-10 Ω·m
Warm streamer: ρ ≈ 10-100 Ω·m

Temperature Ranges

Streamer:

T ≈ 1000-3000 K

Leader:

T ≈ 5000-20000 K

Arc (strike):

T > 10000 K

Validation Criteria

Self-Consistency Checks

Capacitance:

C_sh/L ≈ 2 pF/foot ± 30%

Total resistance:

Within expected range for operating mode (see above)
R_base < R_tip in distributed model

Power balance:

P_spark + losses = P_input (within 20%)

Phase angle:

φ_Z,actual ≥ φ_Z,min (within numerical precision)

Diameter self-consistency:

d_implied ≈ d_nominal (within factor of 2-3)

Warning Flags

Red flags indicating potential errors:

C_sh/L < 1 pF/foot or > 4 pF/foot
R_total < 500 Ω or > 10 MΩ at typical frequencies
φ_Z > -30° or < -85°
Power efficiency > 70% (unrealistically high)
ε < 1 J/m or > 200 J/m
Growth rates > 100 m/s (unphysical for leaders)

Measurement Tolerances

Expected Precision

Capacitance extraction (FEMM):

±10% typical accuracy
±5% with careful meshing

Resistance measurement:

±30-50% (plasma variability dominates)

Field measurements:

E_propagation: ±20-30% (environmental variability)

Energy per meter:

±30-50% (high variability)

Overall model predictions:

Length: ±20-40% typical
Power: ±30-50% typical
Phase: ±5-10° typical

Use these tolerances when validating model against measurements.

This reference compiled from empirical data, community observations, and validated modeling across multiple Tesla coil systems.

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