Rajiv M. Ranade

Etching high aspect ratio silicon trenches

Small ground rule ( 40) trenches in silicon are necessary to achieve required values of cell capacitance in the fabrication of charge-storage capacitors in dynamic random access memory devices. Etching of trenches suffers from a dynamic reactive ion etching (RIE) lag mechanism caused by constriction of trench openings during the etch process. Also, at high aspect ratios (accentuated by constriction of trench openings), reduced ion energy and etchant species flux to the trench bottom (etch front) results in slower etch rates leading to etch stop. This dynamic RIE lag effect and potential etch stop pose significant challenges towards obtaining deeper trenches. In this paper, two methods are proposed to minimize these problems. Short duration cleaning steps, predominantly etching in nature without any builtin deposition component, are used intermittently during the multistep etching sequence. Mask selectivity is preserved as these cleaning steps do not contribute significantly to the mask etch rate. The first method decreases the constriction of the trench opening by thinning the sidewall deposition, thus partially restoring the design dimension of the trench opening. The second method removes the etch-stop or blocking layer at the bottom of the trench without significantly contributing to sidewall thinning. These methods increase the differential etch rate of silicon at high aspect ratios, thereby help achieve the higher silicon depths required to meet the manufacturing process tool utilization targets.

Polysilicon planarization and plug recess etching in a decoupled plasma source chamber using two endpoint techniques

The planarization and recessing of polysilicon to form a plug are processes of increasing importance in silicon IC fabrication. While this technology has been developed and applied to DRAM technology using Trench Storage Capacitors, the need for such processes in other IC applications (i.e. polysilicon studs) has increased. Both planarization and recess processes usually have stringent requirements on etch rate, recess uniformity, and selectivity to underlying films. Additionally, both processes generally must be isotropic, yet must not expand any seams that might be present in the polysilicon fill. These processes should also be insensitive to changes in exposed silicon area (pattern factor) on the wafer. A SF6 plasma process in a polysilicon DPS (Decoupled Plasma Source) reactor has demonstrated the capability of achieving the above process requirements for both planarization and recess etch. The SF6 process in the decoupled plasma source reactor exhibited less sensitivity to pattern factor than in other types of reactors. Control of these planarization and recess processes requires two endpoint systems to work sequentially in the same recipe: one for monitoring the endpoint when blanket polysilicon (100% Si loading) is being planarized and one for monitoring the recess depth while the plug is being recessed (less than 10% Si loading). The planarization process employs an optical emission endpoint system (OES). An interferometric endpoint system (IEP), capable of monitoring lateral interference, is used for determining the recess depth. The ability of using either or both systems is required to make these plug processes manufacturable. Measuring the recess depth resulting from the recess process can be difficult, costly and time- consuming. An Atomic Force Microscope (AFM) can greatly alleviate these problems and can serve as a critical tool in the development of recess processes.