The solderability of a substrate is a measure of the ease with which a soldered joint can be made to that material. Good solderability requires wetting (low contact angle) of the substrate by the solder.[1]

Of metals

Solderability varies depending on the type of solder alloy under discussion. The discussion that follows applies only to unspecified electronic solders[2] (which may include solders that contain lead, now banned for use in nearly all electronic equipment made or sold in the EU). Solderability when using lead-free alloys can differ significantly from solderability when using lead based alloys.

Noble metals may be easy to solder but they have brittle joints. The metals in the good category require a large amount of heat therefore oxidation is an issue. To overcome this a flux is required. For carbon steel, low alloy steel, zinc, and nickel the presence of sulfur creates a brittle joint; lower temperatures are used to minimize this problem. The oxides on the surface of aluminium cause wetting issues and special solders must be used to prevent galvanic corrosion issues. Stainless steel and high alloy steel have a low solderability because the chromium alloying element creates oxides that require aggressive fluxes. The only way that the final category of metals can be soldered is by pre-plating them in a metal that is solderable.[2]

Solderability of various metals[2]
Solderability          Metal          Remarks
ExcellentTin
Cadmium
Gold
Silver
Palladium
Rhodium
Noble metals dissolve easily in solders, resulting in brittle joints.
GoodCopper
Bronze
Brass
Lead
Nickel silver
Beryllium copper
High thermal conductivity of these metals requires high heat input during soldering. Oxidizes quickly so proper flux must be used.
FairCarbon steel
Low alloy steel
Zinc
Nickel
Solder joints become brittle in sulfur-rich environments. Avoid higher temperatures in the presence of lubricants (which contain sulfur).
PoorAluminium
Aluminium bronze
Tough oxides on the surface prevent wetting (formation of the inter-metallic layers). Solders have to be specially selected to avoid galvanic corrosion problems. Tin-zinc solders have proven to be reliable in joining aluminum to aluminum and aluminum to copper.[3] They most often require flux and brushing with a stainless steel brush to break oxide coating to achieve proper bond.
DifficultHigh alloy steel
Stainless steels
Too much chromium oxide. The surface needs to be cleaned with an aggressive flux.
Very DifficultCast iron
Chromium
Titanium
Tantalum
Magnesium
May require pre-plating, or pre-tinning,[4] with a solderable metal or will require the use of a specialized solder.[5]

Testing solderability

Both quantitative and qualitative tests for solderability exist.[6] The two most common testing methods are the 'dip and look' method and wetting balance analysis. In both of these tests, the soldered pieces undergo an accelerated aging process before being tested for solderability, to take into consideration the time a component was in storage prior to mounting to final assembly. The dip and look method is a qualitative test. One form of it is specified as Mil-Std-883 Method 2003. On the other hand, the wetting balance analysis is a quantitative test that measures the wetting forces between molten solder and the test surface as a function of time.

References

  1. Solders, fluxes, and solderability Section 5: Solderability , www.tutorialsweb.com
  2. 1 2 3 Solderability, retrieved 2009-11-30.
  3. Kapp Alloy. "KappAloy". Kapp Alloy & Wire, Inc. Retrieved 23 October 2012.
  4. Kapp Alloy. "Kappa Tinning Compound". Kapp Alloy & Wire, Inc. Retrieved 4 April 2013.
  5. Kapp Alloy GalvRepair. "Kapp GalvRepair". Kapp Alloy & Wire, Inc. Retrieved 23 October 2012.
  6. Solderability Testing www.eesemi.com


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