Electrical characterization of TiN/TiSi 2 and WN/TiSi 2 Cu-diffusion barriers using Schottky diodes

For application of copper in contact level metallization, diffusion barriers between Cu and Si are indispensable. As copper can cause serious deterioration to device performance when diffusion through the barrier occurs, characterization of barrier stability requires extremely sensitive methods for detection of copper. For that purpose, reactively sputtered TiN and WN barriers on SALICIDE TiSi 2 contacts were intensively investigated using capacitance-voltage (C-V) and current-voltage (I-V) measurement on Schottky diode test structures. The results are compared to simultaneously fabricated n + p junction test structures. It is shown that Schottky diode test structures provide early and simple detection of barrier failure, by alteration of the electrical barrier height and by additional diode capacitances. The determined failure temperatures are 600-700°C for TiN/TiSi 2 and 600-800°C for WN/TiSi 2 , depending on the test structure applied. Lower failure temperatures always refer to Schottky diode test structures. The additional capacitances which appear along with barrier failure are significantly frequency and temperature dependent.

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