Method of patterning lead zirconium titanate and barium strontium titanate

Abstract

In an embodiment of the present invention, a method is provided of patterning PZT layers or BST layers. For example, a PZT layer or a BST layer is plasma etched through a high-temperature-compatible mask such as a titanium nitride (TiN) mask, using a plasma feed gas comprising as a primary etchant boron trichloride (BCl ) or silicon tetrachloride (SiCi ). Although BCl or SiCl may be used alone as the etchant plasma source gas, it is typically used in combination with an essentially inert gas. Preferably the essentially inert gas is argon. Other potential essentially inert gases which may be used include xenon, krypton, and helium. In some instances O or N , or Cl , or a combination thereof may be added to the primary etchant to increase the etch rate of PZT or BST relative to adjacent materials, such as the high-temperature-compatible masking material. A TiN masking material can easily be removed without damaging underlying oxides. The selectivity of PZT or BST relative to TiN is very good, with the ratio of the etch rate of the PZT film to the etch rate of the TiN mask typically being better than 20:1. In addition, the etch rate for PZT using a BCl —comprising plasma source gas is typically in excess of 2,000 Å per minute. A substrate bias power is applied to direct ions produced from the BCl or SiCl toward the surface to be etched. The bias power is controlled to avoid sputtering of a conductive layer or layers in contact with the PZT layer, so that the surface of the etched PZT is not contaminated by a conductive material, which can cause the semiconductor device which includes the patterned PZT to short out.