Suppressing Dog-bone Effect in Ultra-high Aspect Ratio (>20:1) Through-hole Electroplating

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Dog-bone Effect refers to the phenomenon where the plating thickness at the via entrance and exit is significantly greater than the middle region during high-aspect-ratio through-hole electroplating. This arises from limited electrolyte mass transfer and uneven current distribution. Below are strategies to suppress it:

1. Electrolyte Formulation Optimization

  • Additive Control:

    • Suppressors (e.g., PEG, imidazole derivatives) adsorb at high-current-density areas (via entrance) to slow deposition (20–30% reduction).

    • Accelerators (e.g., SPS) enhance metal ion reduction in low-current-density regions (via interior).

    • Levelers (e.g., Janus Green B) dynamically balance deposition rates.

    • Optimal Ratios: DoE-guided concentrations (e.g., PEG: 50–200 ppm, SPS: 5–20 ppm).

  • Electrolyte Parameters:

    • High CuSO₄ concentration (200–300 g/L) to improve mass transfer.

    • Low H₂SO₄ (10–50 g/L) and controlled Cl⁻ (50–100 ppm) for additive synergy.

2. Process Parameter Tuning

  • Current Modulation:

    • Pulse Reverse Plating (PRC): Forward current () with periodic reverse dissolution ().

    • Periodic Pulse Reversal (PPR) to redistribute ions.

  • Mass Transfer Enhancement:

    • Jet flow (>2 m/s) or ultrasonic agitation (20–40 kHz) to reduce diffusion layer thickness.

    • Temperature control (25–35°C).

  • Staged Plating: Initial low current () for bottom nucleation, followed by higher current ().

3. Equipment & Auxiliary Design

  • Auxiliary Anodes:

    • Micro IrO₂/Ti anodes near via bottoms to boost local current density by 10–20%.

  • Cathode Shielding:

    • Insulating masks at via entrances to reduce edge field concentration.

  • Rotating Cathode:

    • 10–30 RPM rotation for uniform electrolyte penetration.

4. Via Pretreatment

  • Wall Activation:

    • Electroless Pd or sputtered Au layers to reduce interfacial resistance.

  • Surface Roughening:

    • Plasma etching or H₂SO₄-H₂O₂ micro-etching to enhance adhesion.

5. Simulation & Monitoring

  • Multiphysics Modeling:

    • COMSOL-based current-mass transfer-deposition models to predict plating profiles.

  • In-situ Sensors:

    • Four-point probes for real-time thickness feedback.

6. Validation Metrics

  • Uniformity: FIB-SEM-measured thickness variation <10%.

  • Reliability: No cracks/delamination after 1000 thermal cycles (-55–125°C); resistance drift <5%.