Issue 9, 2000

Abstract

The vapor phase decomposition (VPD) technique is used to dissolve the silicon oxide layer on a Si wafer surface by exposing the wafer to HF vapor. After VPD, the hydrophobic Si wafer surface is scanned with an acidic droplet of solution to extract the surface trace metals. ICP-MS is applied for the determination of metals in the droplet of solution. Matrix effects resulting from the formation of polyatomic species are investigated. The molecular interferences from the presence of different levels of Si concentration left after VPD are investigated. The interference of F on 59Co is found to be negligible and controllable. They are also insignificant for the isotopes of Ga, Cu, Ge and Ni. However, for 47Ti, 68Zn and 44Ca, pronounced matrix effects are observed. A procedure for reducing Si concentration resulting from thick oxide films is carried out and optimum ICP-MS parameters are chosen for the measurement of these samples. Instrumental and method detection limits for 35 elements of interest are determined and provided in this study. Spike recovery for these 35 elements is also performed and the accuracy of the method is confirmed for 34 elements. Silver recovery is poor due to the reduction of this element on the silicon surface. An alternative extraction solution containing HNO3 and HCl is used to collect Ag from the Si wafer surface.

Article information

Article type
Paper
Submitted
28 Feb 2000
Accepted
13 Apr 2000
First published
09 Jun 2000

J. Anal. At. Spectrom., 2000,15, 1211-1216

Advances in trace element analysis of silicon wafer surfaces by vapor phase decomposition (VPD) and inductively coupled plasma mass spectrometry (ICP-MS)

A. Krushevska, S. Tan, M. Passer and X. Rong Liu, J. Anal. At. Spectrom., 2000, 15, 1211 DOI: 10.1039/B001578O

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