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What is the best lead-free surface finish to use for printed circuit board assemblies?

   

Frequently Asked Questions

There are a number of different surface finishes available; the best one to choose will depend on a product's specific application. Some suggestions are included in the table below.

MaterialThickness
(µm)
SolderabilityReflow SurvivabilityShelf LifeCostAdvantagesDisadvantages
Immersion Ag 0.05-0.20 Good 5 reflows 12 months Medium Consistent flat surface for SMT
Good electrical probe surface
Good solderability
Must be recycled quickly if mis-screened
Not available from all suppliers
Multiple board finishes difficult
SnAgCu
HASL
1-25 Good 5 reflows 12 months Medium Good electrical probe surface
Withstands multiple process steps
Good solderability
Higher thermal stress process
No planar surface for SMT
Immersion
Sn
0.75-1.25 Good 5 reflows 12 months Medium Good solderability
Consistent flat surface for SMT
Good electrical probe surface
Must be recycled quickly if mis-screened
Multiple board finishes difficult
Tin whiskers risk
Electroless Ni
Immersion Au
5 Ni
0.05-0.2 Au
V. Good 4 reflows 6 months High Excellent solderability
Consistent flat surface for SMT
Minimal handling issues
Expensive
'Black Pad'
Multiple board finishes difficult
SnCu
HASL
1-25 Good 5 reflows 12 months Medium Good solderability
Good shelf life
Withstands multiple process steps
Wider thickness variation than Sn-Pb HASL
Intermetallics formed before assembly
Electroless Pd 0.15-0.40 Good 5 reflows 12 months High Minimal handling issues
Good solderability
Thick Pd causes brittle joints
Cost
Availability
Organic Solderable Preservative
(OSP)
0.15-0.50 Good 3+ reflows 12 months Low Good planar surface
Low cost
No intermetallics before assembly
Strongest solder joints
Handling concerns; probing issues
Difficult obtaining adequate hole fill
Narrow process window for multiple passes

A consideration when changing to lead-free PCBs is that the board itself will need to withstand the higher processing temperatures for lead-free solder applications; this, like many of the changes required to comply with the RoHS Directive, may have cost implications. When considering laminate properties, some organisations are proposing to use other thermal parameters such as the coefficient of thermal expansion (CTE), time to delamination, and decomposition temperature (Td ), as better predictive indicators than Tg (glass transition temperature). Therefore, not only are increases in Tg necessary, but also decreases in CTE and increases in the Td of the material.

For further assistance from TWI on RoHS and WEEE matters, please  contact us    
   
   What is the WEEE Directive?

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