Antimony stabilizer in an electroless Ni bath
Applications | 2024 | MetrohmInstrumentation
Electroless nickel plating is widely used in printed circuit board manufacturing due to its excellent wear and corrosion resistance. Maintaining the correct level of antimony(III) stabilizer in the plating bath is essential to achieve uniform nickel deposits and high-quality coatings. Rapid and reliable monitoring of Sb(III) concentration helps prevent bath drift and ensures consistent production yield.
This application note describes a straightforward protocol for determining Sb(III) stabilizer levels in electroless nickel plating baths. The approach employs anodic stripping voltammetry (ASV) using the scTRACE Gold sensor integrated with the Metrohm 884 Professional VA analyzer. It can be implemented in both manual and automated workflows to deliver timely process control.
The procedure uses differential pulse (DP) anodic stripping voltammetry:
The method was validated at a target concentration of 1 mg/L Sb(III). A 30 s deposition yielded a clear stripping peak at +0.06 V. The determined concentration was 0.971 mg/L, demonstrating accuracy better than 3 %. By adjusting dilution factors and deposition time, the technique covers a broad concentration range, making it adaptable to various bath formulations.
Advances may include inline process-analytical technology (PAT) integration for real-time feedback, miniaturized sensor arrays for multiplexed measurements of multiple bath additives, and coupling with digital analytics for predictive bath management. Extending ASV methods to other trace stabilizers and contaminants can further optimize electroless plating processes.
This ASV method using the scTRACE Gold sensor and 884 Professional VA provides a robust, accurate, and user-friendly solution for routine monitoring of antimony(III) stabilizer in electroless nickel baths. Its versatility supports both laboratory and automated environments, contributing to process consistency and product quality.
Electrochemistry
IndustriesEnergy & Chemicals
ManufacturerMetrohm
Summary
Importance of Topic
Electroless nickel plating is widely used in printed circuit board manufacturing due to its excellent wear and corrosion resistance. Maintaining the correct level of antimony(III) stabilizer in the plating bath is essential to achieve uniform nickel deposits and high-quality coatings. Rapid and reliable monitoring of Sb(III) concentration helps prevent bath drift and ensures consistent production yield.
Aim and Overview
This application note describes a straightforward protocol for determining Sb(III) stabilizer levels in electroless nickel plating baths. The approach employs anodic stripping voltammetry (ASV) using the scTRACE Gold sensor integrated with the Metrohm 884 Professional VA analyzer. It can be implemented in both manual and automated workflows to deliver timely process control.
Methodology and Instrumentation
The procedure uses differential pulse (DP) anodic stripping voltammetry:
- Sample preparation: 25 µL of plating bath diluted in 10 mL deionized water plus supporting electrolyte.
- Electrode: scTRACE Gold sensor (working, reference and auxiliary electrodes on one ceramic substrate).
- Instrument: Metrohm 884 Professional VA configured for Multi-Mode Electrode.
- Activation: Electrochemical activation of scTRACE Gold before measurement.
- Measurement parameters:
- Deposition potential: –0.10 V
- Deposition time: 30 s
- Potential scan: –0.10 V to 0.20 V
- Peak potential for Sb(III): +0.06 V
- Quantification: Two standard additions of Sb(III) solution to account for matrix effects.
Main Results and Discussion
The method was validated at a target concentration of 1 mg/L Sb(III). A 30 s deposition yielded a clear stripping peak at +0.06 V. The determined concentration was 0.971 mg/L, demonstrating accuracy better than 3 %. By adjusting dilution factors and deposition time, the technique covers a broad concentration range, making it adaptable to various bath formulations.
Benefits and Practical Application
- High sensitivity and selectivity for Sb(III) without extensive electrode maintenance.
- Fast turnaround: total analysis in minutes per sample.
- Compatibility with manual sampling or full automation for inline monitoring.
- Integrated sensor design minimizes handling and calibration steps.
Future Trends and Opportunities
Advances may include inline process-analytical technology (PAT) integration for real-time feedback, miniaturized sensor arrays for multiplexed measurements of multiple bath additives, and coupling with digital analytics for predictive bath management. Extending ASV methods to other trace stabilizers and contaminants can further optimize electroless plating processes.
Conclusion
This ASV method using the scTRACE Gold sensor and 884 Professional VA provides a robust, accurate, and user-friendly solution for routine monitoring of antimony(III) stabilizer in electroless nickel baths. Its versatility supports both laboratory and automated environments, contributing to process consistency and product quality.
Reference
- Metrohm Application Note AN-V-236: Antimony stabilizer in an electroless Ni bath.
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
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