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Understanding PCB/PCBA Ionic Cleanliness Testing

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Importance of Ionic Cleanliness Testing

Ionic contamination on PCBs can lead to several issues, including corrosion, electrochemical migration, and dendritic growth. These problems arise when ionic residues, such as salts and acids, remain on the PCB surface after manufacturing processes like soldering and cleaning. When exposed to moisture, these residues can become conductive, leading to electrical shorts and other failures. Approximately 15% of PCB assembly failures are attributed to ionic contamination, highlighting the need for rigorous testing.

Ensuring ionic cleanliness is vital for maintaining device reliability, especially in high-stakes industries like aerospace, medical devices, and military applications. By adhering to industry standards, manufacturers can enhance product quality, reduce warranty claims, and improve customer satisfaction.

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Figure 1 IPC B-52 test coupon comprises a SIR test coupon (SIR) and a section for ionic contamination measurements (SIR).

Methods of Ionic Cleanliness Testing

Several methods are commonly used to assess ionic cleanliness:

Resistivity of Solvent Extract (ROSE) Test: This method involves immersing a PCB in a solvent solution to extract ionic contaminants. The resistivity of the solution is measured, with lower resistivity indicating higher contamination levels. ROSE testing is quick and provides a general indication of cleanliness but cannot identify specific contaminants.

Ion Chromatography (IC): A more advanced technique, IC identifies and quantifies specific ionic species present on the PCB. This method provides detailed insights into contamination sources, aiding in process improvement, though it is more complex and time-consuming.

Surface Insulation Resistance (SIR) Testing: SIR testing measures the resistance offered by ionic residues to current flow across PCB traces. It simulates conditions that promote electrochemical migration, providing insights into long-term reliability.

Localized Ionics Testing: This method focuses on specific PCB areas, allowing for targeted analysis of contamination. It is particularly useful for detecting localized issues that broader methods might miss.

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Figure 2. Electrochemical migration interferes with current measurements in a PCB.

Standards and Guidelines

Ionic cleanliness testing is governed by industry standards, primarily set by the IPC (Institute for Printed Circuits). These standards, such as IPC-TM-650, outline acceptable levels of ionic contamination and testing procedures. Compliance with these standards ensures that PCBs meet necessary quality benchmarks before deployment in critical applications.

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Figure 3 Localized extraction method (under SMT low stand off area)

Conclusion

In conclusion, PCB/PCBA ionic cleanliness testing is an essential practice that safeguards the reliability and performance of electronic devices. By employing various testing methods and understanding the sources of contamination, manufacturers can ensure their products meet industry standards while minimizing risks associated with ionic residues. This proactive approach not only enhances product quality but also contributes to long-term cost savings and customer satisfaction. As technology continues to advance, maintaining high standards for cleanliness will remain a cornerstone of successful electronics manufacturing.