Report Tin Whisker Testing UMT 250 INHALTSVERZEICHNIS 1 INTRODUCTION... 2 2 INEMI TIN WHISKER USER GROUP TEST PROCEDURE... 2 3 INEMI TESTING... 3 4 ACCEPTANCE CRITERIA... 3 5 IMAGES... 4 6 CONCLUSION... 8 1 of 8 18.02.2010
1 Introduction The European Union s directive, the Reduction on Hazardous Substances (RoHS), sets phase-out dates for the use of lead (Pb) and several other materials used in electronic products in July 2006. The rapid transition away from tin lead terminations to materials such as 100% tin has caused concern about the phenomenon of tin whisker growth. Tin whiskers are crystalline structures that can grow from surfaces plated with pure tin. The whiskers are electrically conductive and hence can cause concern over circuits being re-wired from random whisker growth. While tin whiskers are hot topics in the general electronics industry more fundamental research is required to understand them. Today, much mystery enshrouds tin whiskers as it is unknown what mechanisms are required to form a whisker and what mechanisms cause the whiskers to grow. Without such definitive answers no universal solution has been found to guarantee prevention of tin whisker growth. Since no solution is in existence, tests have been designed to accelerate tin whisker growth and hence try and find electronic components that are susceptible to tin whisker growth. One such test procedure is the inemi Tin Whisker Acceptance Test Requirements (JEDEC STANDARD JESD201 and JESD22A121.01). The mentioned document address the requirements for tin whisker mitigation practices and tin whisker testing necessary for user acceptance of pure tin, or high tin content tin alloy finishes over base materials typically used in lead frame type applications. The following report details these tests as were performed on the UMT250 product family which uses pure tin over nickel plated base material. 2 inemi Tin Whisker User Group Test procedure The following table shows the tests performed on the Fuse UMT250 samples in order to accelerate the growth of tin whiskers. These test conditions represent a minimum set of conditions that shall be used to assess the propensity for tin whisker growth on any given tin finish under study: Flow Thermal Cycling Ambient storage High Temperature/Humidity storage Test Condition 1 500 cycles, 3 cycles/hr, Min Temp -55 to -40 (+0/-10 ) C, Max Temp +85 (+10/-0 ) C, air to air; 5 to 10 minutes, Inspection intervals 500cycles/1000cycles/1500cycles 4 000 hrs @ 30±2 C and 60±3% RH, Inspection intervals 1000hrs/2000hrs/3000hrs/4000hrs 4 000 hrs @ 60±5 C and 87+3/-2% RH, Inspection intervals 1000hrs/2000hrs/3000hrs/4000hrs Preconditioning was used before each test. The preconditioning details were as follows: Item Details Preconditioning Storage at room temperature for 4 weeks Assembly SnPb Solder reflowed at 215 C Assembly Pb-free Solder reflowed at 255 C Once the samples were tested to the above procedure, they were inspected using an optical microscope Leica MZ 16A capable of detecting whiskers with a minimum axial length of 10 microns. 2 of 8 18.02.2010
3 inemi Testing The inspection areas for tin whisker growth of the Fuse UMT250 are outlined below. Tin Surface Type Sn over Ni and brass Type UMT250 a e f g b d h c 4 Acceptance Criteria 3 of 8 18.02.2010
Test results The following tables outline the results of tin whisker growth on the samples after the three testing conditions. Tin Whisker Inspection after Temperature Cycling Part number Preinspection 500 Temp. Cycling 1000 Temp. Cycling 2000 Temp. Cycling UMT250 No Whisker No Whisker No Whisker No Whisker Tin Whisker Inspection after Ambient Temperature Humidity Storage Part number Ambient Storage 1000hrs Ambient Storage 2000hrs Ambient Storage 3000hrs Ambient Storage 4000hrs UMT250 No Whisker No Whisker No Whisker No Whisker Tin Whisker Inspection after High Temperature Humidity Storage Part number UMT250 High Storage 1000hrs Whisker Area Where No Whisker - High Storage 2000hrs Whisker Area Where No Whisker - High Storage 3000hrs Whisker Area Where No Whisker - High Storage 4000hrs Whisker Area Where No Whisker - 5 Images **New state** Picture 1: UMT250 (section e) Picture 2: UMT250 (section a) 4 of 8 18.02.2010
SCHURTER AG **After 1500 Temperature Cycling test** No Preconditioning Picture 1: UMT250 (section a) Picture 2: UMT250 (section b) Precondition: Sn/Pb Solder reflowed at 215 C Picture 3: UMT250 (section d) Picture 4: UMT250 (section e) Precondition: Pb-free Solder reflowed at 255 C Picture 5: UMT250 (section c) Picture 6: UMT250 (section f) Page Created date: Created by: Released date: Released by: Document No. Index 5 of 8 18.02.2010 SKA 09.03.2010 HRÜ 0108.2708 _
SCHURTER AG ** After 4000hrs Ambient Temperature Humidity Storage** No Precondition Picture 7: UMT250 (section c) Picture 8: UMT250 (section h) Precondition: Sn/Pb Solder reflowed at 215 C Picture 9: UMT250 (section d) Picture 10: UMT250 (section e) Precondition: Pb-free Solder reflowed at 255 C Picture 11: UMT250 (section a) Picture 12: UMT250 (section b) Page Created date: Created by: Released date: Released by: Document No. Index 6 of 8 18.02.2010 SKA 09.03.2010 HRÜ 0108.2708 _
SCHURTER AG **After 4000hrs High Temperature Humidity Storage Test** No Precondition Picture 13: UMT250 (section d) Picture 14: UMT250 (section e) Precondition: Sn/Pb Solder reflowed at 215 C Picture 15: UMT250 (section a) Picture 16: UMT250 (section b) Precondition: Pb-free Solder reflowed at 255 C Picture 17: UMT250 (section f) Picture 18: UMT250 (section g) Page Created date: Created by: Released date: Released by: Document No. Index 7 of 8 18.02.2010 SKA 09.03.2010 HRÜ 0108.2708 _
6 Conclusion The tests where performed on a total number of 81 pieces UMT250. We could not find any whisker growth over 15µm during and at the end of the three test conditions. 9.02.2010 Peter Straub, Manager Circuit Protection 8 of 8 18.02.2010