A polishing application uses alkali, colloidal silica for polishing silicate-based glasses. Preferably, the silica solutions are adjusted to a pH of or above 10. The polished silicate-based glass surfaces have surface finishes consistently below 2 .ANG. Ra. The unique method first polishes a surface of the substrate with an aqueous solution of at least one metal oxide abrasive and further polishes the surface of the substrate with an alkali aqueous solution of colloidal silica. Preferably, to the final smoothness of 2 .ANG. Ra or less.
The development of colloidal silica as a polishing abrasive is two fold. Colloidal silica has a spherical morphology and varied particle size (typically 20-50 nm diameter) which minimizes scratches in softer materials. By mixing colloidal silica in aqueous solution for polishing materials such as aluminum and silicon, the surface of the metal substrate hydrolyses and permits the abrasive nature of the colloidal silica to remove the reaction layer, while minimizing interactions with an underlying surface.
For glass polishing, pH is most commonly adjusted to be acidic in order to prevent dissolution of the glass surface. This procedure has resulted in part from the fact that the different glasses will corrode and form reaction layers in widely varying fashions. By polishing glass at a relatively low pH, the glass surface does not corrode, but rather has the opportunity to chemo-mechanically interact with the cerium oxide abrasive and promote removal in a controlled manner.
DISCLOSURE OF INVENTION
The present invention is a process for the application of alkali, colloidal silica for polishing silicate based glasses, such as fused silica aluminosilicates borosilicates titania-silicates, or corrosion resistant mixed alkali glasses. Preferably, the silica solutions are adjusted to a pH of or above 10. The polished silicate-based glass surfaces have surface finishes consistently below 2 .ANG. Ra. Most preferably, the surface finish is about 1 .ANG. Ra.
Although colloidal silica in neutral and acidic environments has certainly been applied to various glasses with mixed results, this invention results in the processing of highly polished surfaces for fused silica by the controlled polishing with colloidal silica adjusted above pH 10. By first polishing the glass to a surface finish below 10 .ANG. using conventional abrasives, the application of the colloidal silica in a second polishing step allows for the improvement in surface quality by the combination of surface corrosion by the alkali solution and removal of the continually-forming hydrated surface layer by the spherical colloidal silica. We also have found small particle size colloidal silica to be preferred. In comparison to colloidal silica polishing of glass at lower pH, the solubility of the glass surface and the stability of the colloidal solution interfere with and prevent significant improvements in surface finish. Critical to this finishing protocol is the need to remove surface and subsurface damage prior to the colloidal silica polishing step in order to prevent the alkali solution from etching the damaged areas. Furthermore, a soft polishing pad must be used during the colloidal silica polishing step to prevent damage commonly induced when hard pads contact the glass surface during colloidal abrasive polishing.
BEST MODE OF CARRYING OUT INVENTION
Our process centers on the use of a commercially available, colloidal silica polishing abrasive marketed for microelectronics applications.
Our method for final polishing silica substrates comprises the steps of providing a silica substrate, first polishing a surface of the substrate with an aqueous solution of at least one metal oxide abrasive to a surface roughness Ra ranging from 6 to 10 .ANG.; and further polishing the surface of the substrate with an alkali aqueous solution of colloidal silica to a surface roughness Ra of 5 .ANG. or less. Preferably, the first polishing step polishes the surface of the substrate to a surface roughness Ra of about 8 .ANG.. Preferably, the further polishing step polishes the surface of the substrate to surface roughness Ra of about 2 .ANG. or less.
The metal oxide abrasive is alumina, titania, zirconia, germania, silica or ceria. Preferably, the metal oxide abrasive is cerium oxide.
Generally, the aqueous solution of colloidal silica is buffered to a pH ranging from 8 to 12 or 10-15. Preferably, the aqueous solution of colloidal silica is buffered to a pH ranging from 10.5 to 13.5.
Generally, the colloidal silica has an average particle size of 50 nm or less.
The process depends on surface corrosion by the alkali solution and partially on a preferred removal of microscopic peaks on the glass surface by abrasive pad interactions with the surface to promote improved overall roughness qualities through reducing peak-to-valley heights on both macroscopic and microscopic scales. Typically, the particle size ranges from 10 to 50 nm and preferably ranges from 20 to 50 nm. Particle size and surface area dimensions are understood to be greater than zero.
In one embodiment, the colloidal silica acts as a cleaning agent and removes any residual abrasive from previous polishing steps. For example, the colloidal silica removes any remaining cerium oxide from the first polishing step.
Generally, the silica substrate is made of silica, fused silicates, or glasses thereof. Preferably, the silica substrate is fused silica.
Typically, a hard polishing pad carries out the first polishing step and a soft polishing pad carries out the further polishing step. Preferably, the hard polishing pad is a blown polyurethane and the soft polishing pad is a napped polyurethane.
EXAMPLE
Samples of fused silica glass were machined via grinding and lapping processes to form a flat surface with minimal subsurface damage. A first polishing step was applied to each sample using a cerium oxide abrasive (Ferro Corporation, Product Code 482) and a hard polishing pad (Rodel Incorporated, Product Code MHC-14B), thus generating a surface finish of Ra=8 .ANG. (Table 1). The abrasive used for the second polish was a commercially available colloidal silica (Cabot Corporation, Product Code A2095). The colloidal silica had a surface area of 200 m.sup.2 /g or less. The solution had been dispersed to a pH of 10, and was used in combination with a soft polishing pad (Rodel Incorporated, Product Code 204). Final surface finishes were measured using an atomic force microscope to have a Ra less than 2 .ANG. (Table 2).
Table 1 below shows atomic force micrograph of fused silica surfaces polished using cerium oxide as first polishing step.
TABLE 1
Image Statistics
Img. Z range 47.947 nm
Img. Mean -0.0002 nm
Img. Rms (Rq) 1.636 nm
Img. Ra 1.034 nm (10.34.ANG.)
Table 2 below shows atomic force micrograph of fused silica surfaces polished using colloidal silica at a pH 10-11 as a second and final polishing step. The fused silica surface had a roughness (smoothness) of 1.73 .ANG..
TABLE 2
Image Statistics
Img. Z range 5.179 nm
Img. Mean -0.00005 nm
Img. Rms (Rq) 0.173 nm (1.73.ANG.)
Img. Ra 0.135 mn
The data shows that colloidal silica in a pH 10 solution for polishing fused silica has proven effective in generating fine surface finishes with Ra<2 .ANG.. This fine of a surface finish could not be generated for lower pH solutions for colloidal silica due to the low solubility of glass at low pH. The data shows the usefulness of a commercially available, colloidal silica polishing abrasive for the microelectronics field. The polishing protocol of using colloidal silica dispersed to pH 10 for polishing fused silica coupled with using the dispersion in a second polishing step provides superpolished surfaces which the industry previously could not provide.
Z range is the ratio of peaks to valleys on the polished surface. Rq is the root means square of the roughness. Ra is the average roughness. The key measurement is Ra.
In addition to these embodiments, persons skilled in the art can see that numerous modifications and changes may be made to the above invention without departing from the intended spirit and scope thereof.
