Dielectric films for narrow gap-fill applications

Semiconductor device manufacturing: process – Packaging or treatment of packaged semiconductor – Including adhesive bonding step

Reexamination Certificate

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C438S778000

Reexamination Certificate

active

06444495

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates generally to dielectric materials for use in semiconductor devices, and, more specifically to dielectric materials, prepared from colloidal dispersions, that have high thermal stability and etch resistance and completely fill narrow gaps.
BACKGROUND
In order to provide integrated circuits (ICs) with increased performance, the characteristic dimensions of devices and spacings on the ICs continue to be decreased. Fabrication of such devices often requires the deposition of dielectric materials into features patterned into layers of material on silicon substrates. In most cases it is important that the dielectric material completely fill such features, which may be as small as 0.01 to 0.05 &mgr;m or even smaller in next generation devices. Filling such narrow features, so-called gap filling, places stringent requirements on materials used, for example, for pre-metal dielectric (PMD) or shallow trench isolation (STI) applications. The pre-metal dielectric layer on an integrated circuit isolates structures electrically from metal interconnect layers and isolates them electrically from contaminant mobile ions that degrade electrical performance. PMD layers may require filling narrow gaps having aspect ratios, that is the ratio of depth to width, of five or greater. After deposition, the dielectric materials need to be able to withstand processing steps, such as high temperature anneal, etch, and cleaning steps.
Dielectric materials are commonly deposited by chemical vapor deposition (CVD) or by spin-on processes. Each of these approaches has some limitations for filling very narrow gaps. Plasma enhanced chemical vapor deposition (PECVD) processes provide high deposition rates at comparatively low temperatures (about 400° C.). The main drawback is that PECVD processes have a lower deposition rate inside a gap than at other locations on a surface. The differential deposition rates can create structures overhanging a gap opening, leading to voids within the gap. Typically, for spacings less than 0.25 &mgr;m, depending on the aspect ratio, it is difficult to achieve void-free gap fill using standard PECVD approaches.
Phosphosilicate glass (PSG) and borophosphosilicate glass (BPSG) are commonly used for premetal dielectric applications. The films are usually deposited using atmospheric pressure CVD (APCVD), sub-atmospheric pressure CVD (SACVD) or low pressure CVD (LPCVD). Depending on the process conditions and precursors used these methods can achieve an almost conformal coating. Gap-fill is achieved by a post-deposition reflow process in which the material is treated at high temperatures, typically 800-1200° C. The inclusion of phosphorous and boron, in particular, the boron, in the glass lower the glass transition and flow temperatures. However, the use of CVD followed by reflow in future advanced devices will be limited by the high thermal budget required for the reflow process, which is not compatible with certain materials and processes, such as cobalt silicide used at the contact level. For very narrow gaps, less than 0.2 &mgr;m, there is an increasing risk that voids may remain, even after high temperature processing.
Some workers have used high density plasma chemical vapor deposition (HDP CVD) to improve gap-fill of PSG and BPSG. In the high density plasma process, deposition and etching occur simultaneously. Etching is most efficient at the top comers of narrow openings, thereby compensating for a lower deposition rate inside the gap. HDP CVD deposition does not require high temperature processing, although an anneal step can be used if a denser film is desired. The HDP CVD process has the drawback that for narrower structures, lower deposition to etch ratios have to be used resulting in a relatively slow overall filling rate. Improved gap-fill may also require modifications in the design of device features, such as rounded comers and sloped sidewalls. Finally, there is also a concern about plasma damage to the device during HDP CVD processing.
Spin-on glasses and spin-on polymers such as silicates, siloxanes, silazanes or silisequioxanes generally have good gap-fill properties. The films of these materials are typically formed by applying a coating solution containing the polymer followed by a bake and thermal cure process. The utility of these spin-on materials may be limited, however, by material shrinkage during thermal processing. Thermal shrinkage is a key consideration for materials which have to withstand high process temperatures, such as materials used for pre-metal dielectric and/or shallow trench isolation applications, which may involve process temperatures exceeding 800° C. High shrinkage can lead to unacceptable film cracking and/or formation of a porous material, particularly inside narrow gaps. Cracked or porous material may have an undesirably high wet etch rate in subsequent process steps.
Thus there remains a need for a dielectric material that provides void-free gap-fill of narrow features at processing temperatures less than the reflow temperatures used currently. The gap-filling materials need to have high thermal stability and reasonable resistance to etching solutions to survive subsequent processing steps.
SUMMARY
A colloidal dispersion of particles composed of a dense material dispersed in a solvent is used in forming a gap-filling dielectric material with low thermal shrinkage. The particles are preferably of nanometer-scale dimensions and are termed nanoparticles. The dense material is either a dielectric material or a material convertible to a dielectric material by oxidation or nitridation. The dielectric material is particularly useful for pre-metal dielectric and shallow trench isolation applications. Oxides and nitrides of silicon, oxides and nitrides of aluminum, and oxides and nitrides of boron are useful as nanoparticle materials. Colloidal silica is particularly useful as the colloidal dispersion. The dielectric material optionally includes dopant species such as arsenic, antimony, phosphorous, or boron.
According to the methods of forming a dielectric material, the colloidal dispersion is deposited on a substrate and the deposited film is dried forming a porous intermediate layer. The intermediate layer is modified by infiltration with a liquid phase matrix material, followed by curing, where, in all cases, curing includes optionally annealing, by infiltration with a gas phase matrix material, followed by curing, or by curing alone, to provide a gap-filling, thermally stable, etch resistant dielectric material.
Infiltrating matrix materials applied in the liquid phase are spin-on polymers, including oligomers and monomers, that can be converted to silica or similar ceramic materials on high temperature cure, optionally in the presence of oxygen or steam. The matrix materials include, but are not limited to, silicates, hydrogen silsesquioxanes, organosilsesquioxanes, organosiloxanes, silsesquioxane-silicate copolymers, silazane-based materials, polycarbosilanes, and acetoxysilanes. The liquid matrix materials optionally include dopant species such as arsenic, antimony, phosphorous, or boron. In liquid phase infiltration, a coating solution of the matrix material is applied on the colloidal film.
Gas phase infiltration uses chemical vapor deposition (CVD) methods under conditions in which impinging molecules have a low sticking coefficient and/or high surface diffusion to avoid sealing a top surface of a narrow gap before bulk porosity of the intermediate layer is reduced. The CVD deposited materials optionally include dopant species. Other gas phase deposition processes, such as atomic layer deposition, may also be used for gas phase infiltration.
The dried intermediate layer or the infiltrated intermediate layer is cured, for example in a furnace at temperatures of between about 600 and 800° C. or by rapid thermal processing, for example, at temperatures of between about 700 and 900° C. Optionally, one or more bake steps at temperatures, for example, between about 75 and 300° C. preced

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