Electromagnetic Coupling

Coupling outputs connect Q3D extraction to qubit-qubit, qubit-resonator, and

package-mode interactions.

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Parameter

Symbol / Unit

Extraction Method

Typical Q3D Value

Ideal / Optimal

Good Range

Worst Case

Why It Matters

Key Design Note

34

External Quality Factor (Q_ext)

Q_ext

HFSS eigenmode + Q3D coupling capacitance extraction

10³ – 10⁵

5×10³ – 2×10⁴ (dispersive readout)

10³ – 10⁵

< 500 or > 10⁶

Sets readout bandwidth κ = ω_r/Q_ext and Purcell loss rate; undercoupled →

slow; overcoupled → Purcell

Purcell limit: T₁_Purcell = Q_ext/ω_r × (Δ/g)²; Purcell filter relaxes this

trade-off

35

Internal Quality Factor (Q_int)

Q_int

VNA transmission measurement; HFSS loss tangent input

> 10⁶ (planar Al at 4K)

> 10⁶

10⁵ – 10⁶

< 10⁴

Intrinsic resonator loss from TLS, dielectric, radiation; directly sets T₁

floor via Purcell

Q_int > 10⁶ requires: HR-Si or sapphire substrate, clean metal

deposition, minimal surface TLS

36

Loaded Quality Factor (Q_L)

Q_L

1/Q_L = 1/Q_int + 1/Q_ext; VNA S21 Lorentzian fit

10³ – 10⁴

10³ – 10⁴ (balanced readout)

500 – 2×10⁴

< 200 or > 10⁵

Determines resonator 3 dB bandwidth; BW = f_r/Q_L sets speed vs SNR tradeoff

for readout

In practice Q_L ≈ Q_ext when Q_int >

> Q_ext (under-coupled limit is common design choice)

37

CPW Characteristic Impedance (Z_0)

Z_0 / Ω

Q3D RLGC → Z_0 = √(L’/C’); verified by HFSS S11 calibration

50 Ω ± 1 Ω

50 Ω ± 1 Ω

45 – 55 Ω

< 30 or > 80 Ω

Impedance mismatch causes reflections degrading signal integrity; Z_0

controlled by trace/gap ratio

On 500 μm Si: 10 μm trace / 6 μm gap → Z_0 ≈ 50 Ω; wider trace → lower Z_0

38

Effective Permittivity (varepsilon_eff)

varepsilon_eff

Q3D electrostatic fill factor calculation; HFSS eigenmode

6.0 – 6.5 (CPW on Si)

6.0 – 6.5

5.5 – 7.0

< 4 or > 9

Sets propagation velocity v_ph = c/√varepsilon_eff and resonator physical

length for target frequency

varepsilon_eff depends on substrate filling fraction; varepsilon_eff ≈ (1 +

εr)/2 for CPW in air on substrate

39

Coupling Coefficient k^2

k^2 / ×10⁻³

Q3D capacitance ratio k^2 = C_g² / (C_1 × C_2)

1 – 10 ×10⁻³

1 – 10 ×10⁻³

0.5 – 20 ×10⁻³

< 0.1 or > 50 ×10⁻³

Power transfer efficiency between resonator and feedline; determines Q_ext

directly

k^2 ∝ gap width at coupling capacitor; etch depth variation of 0.1 μm →

δk²/k^2 ~ 5%