Abstract: Aspects of the disclosure pertain to methods of depositing silicon oxide layers on substrates. In embodiments, silicon oxide layers are deposited by flowing a silicon-containing precursor having a Si—O bond, an oxygen-containing precursor and a second silicon-containing precursor, having both a Si—C bond and a Si—N bond, into a semiconductor processing chamber to form a conformal liner layer. Upon completion of the liner layer, a gap fill layer is formed by flowing a silicon-containing precursor having a Si—O bond, an oxygen-containing precursor into the semiconductor processing chamber. The presence of the conformal liner layer improves the ability of the gap fill layer to grow more smoothly, fill trenches and produce a reduced quantity and/or size of voids within the silicon oxide filler material.

Abstract: Method and systems for patterning a hardmask film using ultraviolet light is disclosed according to one embodiment of the invention. Embodiments of the present invention alleviate the processing problem of depositing and etching photoresist in order to produce a hardmask pattern. A hardmask layer, such as, silicon oxide, is first deposited on a substrate within a deposition chamber. In some cases, the hardmask layer is baked or annealed following deposition. After which, portions of the hardmask layer are exposed with ultraviolet light. The ultraviolet light produces a pattern of exposed and unexposed portions of hardmask material. Following the exposure, an etching process, such as a wet etch, may occur that removes the unexposed portions of the hardmask. Following the etch, the hardmask may be annealed, baked or subjected to a plasma treatment.

Abstract: A substrate processing system that has a plurality of deposition chambers, and one or more robotic arms for moving a substrate between one or more of a deposition chamber, load lock holding area, and a curing and treatment module. The substrate curing and treatment module is attached to the load-lock substrate holding area, and may include: The curing chamber for curing a dielectric layer in an atmosphere comprising ozone, and a treatment chamber for treating the cured dielectric layer in an atmosphere comprising water vapor. The chambers may be vertically aligned, have one or more access doors, and may include a heating system to adjust the curing and/or heating chambers between two or more temperatures respectively.

Abstract: This disclosure provides a fuel injector system and method in which the timing of events in during period of fuel injection of a piezoelectric-actuated fuel injector are estimated based on sensed forces within the injector. The force sensor is positioned between a piezoelectric actuator and a hydraulic link assembly mechanically coupled with the piezoelectric actuator, and the force sensor operable to output a signal corresponding to forces between the piezoelectric actuator and the hydraulic link assembly. From information contained in the sensor output signal, timing in the injection period of at least one fueling characteristic based can be estimated to allow for adjusting fuel injector characteristics to compensate for variations affecting fuel injection, such as manufacturing tolerances, environmental conditions, and deterioration/wear.

Abstract: Methods for doping a non-planar structure by forming a conformal doped silicon glass layer on the non-planar structure are disclosed. A substrate having the non-planar structure formed thereon is positioned in chemical vapor deposition process chamber to deposit a conformal SACVD layer of doped glass (e.g. BSG or PSG). The substrate is then exposed to RTP or laser anneal step to diffuse the dopant into the non-planar structure and the doped glass layer is then removed by etching.

Abstract: A method for forming a multi-layer silicon oxide film on a substrate includes performing a deposition cycle that comprises depositing a silicon oxide layer using a thermal chemical vapor deposition (CVD) process and depositing a silicon oxide layer using a plasma enhanced chemical vapor deposition (PECVD) process. The deposition cycle is repeated a specified number of times to form the multi-layer silicon oxide film comprising a plurality of silicon oxide layers formed using the thermal CVD process and a plurality of silicon oxide layers formed using the PECVD process. Each silicon oxide layer formed using the thermal CVD process is adjacent to at least one silicon oxide layer formed using the PECVD process.

Abstract: Methods of decreasing the effective dielectric constant present between two conducting components of an integrated circuit are described. The methods involve the use of a gas phase etch which is selective towards the oxygen-rich portion of the low-K dielectric layer. The etch rate attenuates as the etch process passes through the relatively high-K oxygen-rich portion and reaches the low-K portion. The etch process may be easily timed since the gas phase etch process does not readily remove the desirable low-K portion.

Abstract: Methods of forming a dielectric layer are described. The methods include the steps of mixing a silicon-containing precursor with a plasma effluent, and depositing a silicon-and-nitrogen-containing layer on a substrate. The silicon-and-nitrogen-containing layer is converted to a silicon-and-oxygen-containing layer by curing in an ozone-containing atmosphere in the same substrate processing region used for depositing the silicon-and-nitrogen-containing layer. Another silicon-and-nitrogen-containing layer may be deposited on the silicon-and-oxygen-containing layer and the stack of layers may again be cured in ozone all without removing the substrate from the substrate processing region. After an integral multiple of dep-cure cycles, the conversion of the stack of silicon-and-oxygen-containing layers may be annealed at a higher temperature in an oxygen-containing environment.

Abstract: Aspects of the disclosure pertain to methods of preferentially filling narrow trenches with silicon oxide while not completely filling wider trenches and/or open areas. In embodiments, dielectric layers are deposited by flowing a silicon-containing precursor and ozone into a processing chamber such that a relatively dense first portion of a silicon oxide layer followed by a more porous (and more rapidly etched) second portion of the silicon oxide layer. Narrow trenches are filled with dense material whereas open areas are covered with a layer of dense material and more porous material. Dielectric material in wider trenches may be removed at this point with a wet etch while the dense material in narrow trenches is retained.

Abstract: Methods are provided for processing a substrate for depositing an adhesion layer having a low dielectric constant between two low k dielectric layers. In one aspect, the invention provides a method for processing a substrate including depositing a barrier layer on the substrate, wherein the barrier layer comprises silicon and carbon and has a dielectric constant less than 4, depositing a dielectric initiation layer adjacent the barrier layer, and depositing a first dielectric layer adjacent the dielectric initiation layer, wherein the dielectric layer comprises silicon, oxygen, and carbon and has a dielectric constant of about 3 or less.

Abstract: A method of etching silicon oxide from a narrow trench and a wide trench (or open area) is described which allows the etch in the wide trench to progress further than the etch in the narrow trench. The method includes two dry etch cycles. The first dry etch cycle involves a low intensity or abbreviated sublimation step which leaves solid residue in the narrow trench. The remaining solid residue inhibits etch progress in the narrow trench during the second dry etch cycle allowing the etch in the wide trench to overtake the etch in the narrow trench.

Abstract: Aspects of the disclosure pertain to methods of depositing dielectric layers on patterned substrates. In embodiments, dielectric layers are deposited by flowing BIS(DIETHYLAMINO)SILANE (BDEAS), ozone and molecular oxygen into a processing chamber such that a relatively uniform dielectric growth rate is achieved across the patterned substrate surface. The deposition of dielectric layers grown according to embodiments may have a reduced dependence on pattern density while still being suitable for non-sacrificial applications.

Abstract: Methods of depositing silicon oxide layers on substrates involve flowing a silicon-containing precursor, an oxidizing gas, water and an additive precursor into a processing chamber such that a uniform silicon oxide growth rate is achieved across the substrate surface. The surface of silicon oxide layers grown according to embodiments may have a reduced roughness when grown with the additive precursor. In other aspects of the disclosure, silicon oxide layers are deposited on a patterned substrate with trenches on the surface by flowing a silicon-containing precursor, an oxidizing gas, water and an additive precursor into a processing chamber such that the trenches are filled with a reduced quantity and/or size of voids within the silicon oxide filler material.

Abstract: Processes for forming high density gap-filling silicon oxide on a patterned substrate are described. The processes increase the density of gap-filling silicon oxide particularly in narrow trenches. The density may also be increased in wide trenches and recessed open areas. The densities of the gap-filling silicon oxide in the narrow and wide trenches/open areas become more similar following the treatment which allows the etch rates to match more closely. This effect may also be described as a reduction in the pattern loading effect. The process involves forming then planarizing silicon oxide. Planarization exposes a new dielectric interface disposed closer to the narrow trenches. The newly exposed interface facilitates a densification treatment by annealing and/or exposing the planarized surface to a plasma.

Abstract: Aspects of the disclosure pertain to methods of depositing conformal silicon oxide layers on patterned substrates. In embodiments, dielectric layers are deposited by flowing a silicon-containing precursor and ozone into a processing chamber such that a relatively uniform dielectric growth rate is achieved across the patterned substrate surface having heterogeneous materials and/or a heterogeneous pattern density distribution. The deposition of dielectric layers grown according to embodiments may have a reduced dependence on underlying material and pattern density while still being suitable for non-sacrificial applications. Reduction in dependence on pattern density is achieved by terminating deposition near the end of an incubation period. Multiple deposition cycles may be conducted in series since the beneficial nature of the incubation period may repeat after a pause in deposition.

Abstract: A method of forming a silicon oxide layer is described. The method may include the steps of mixing a carbon-free silicon-containing precursor with a radical-nitrogen precursor, and depositing a silicon-and-nitrogen-containing layer on a substrate. The radical-nitrogen precursor is formed in a plasma by flowing ammonia and nitrogen (N2) and/or hydrogen (H2) into the plasma in order to allow adjustment of the nitrogen/hydrogen ratio. The silicon-and-nitrogen-containing layer may be converted to a silicon-and-oxygen-containing layer by curing and annealing the film.

Abstract: Methods of forming dielectric layers are described. The method may include the steps of mixing a silicon-containing precursor with a radical-nitrogen precursor, and depositing a dielectric layer on a substrate. The radical-nitrogen precursor is formed in a remote plasma by flowing hydrogen (H2) and nitrogen (N2) into the plasma in order to allow adjustment of the nitrogen/hydrogen ratio. The dielectric layer is initially a silicon-and-nitrogen-containing layer which may be converted to a silicon-and-oxygen-containing layer by curing and/or annealing the film in an oxygen-containing environment.

Abstract: Methods are provided for processing a substrate for depositing an adhesion layer having a low dielectric constant between two low k dielectric layers. In one aspect, the invention provides a method for processing a substrate including depositing a barrier layer on the substrate, wherein the barrier layer comprises silicon and carbon and has a dielectric constant less than 4, depositing a dielectric initiation layer adjacent the barrier layer, and depositing a first dielectric layer adjacent the dielectric initiation layer, wherein the dielectric layer comprises silicon, oxygen, and carbon and has a dielectric constant of about 3 or less.

Abstract: Methods for doping a non-planar structure by forming a conformal doped silicon glass layer on the non-planar structure are disclosed. A substrate having the non-planar structure formed thereon is positioned in chemical vapor deposition process chamber to deposit a conformal SACVD layer of doped glass (e.g. BSG or PSG). The substrate is then exposed to RTP or laser anneal step to diffuse the dopant into the non-planar structure and the doped glass layer is then removed by etching.

Abstract: The formation of a gap-filling silicon oxide layer with reduced tendency towards cracking is described. The deposition involves the formation of a flowable silicon-containing layer which facilitates the filling of trenches. Subsequent processing at high substrate temperature causes less cracking in the dielectric film than flowable films formed in accordance with methods in the prior art. A compressive liner layer deposited prior to the formation of the gap-filling silicon oxide layer is described and reduces the tendency for the subsequently deposited film to crack. A compressive capping layer deposited after a flowable silicon-containing layer has also been determined to reduce cracking. Compressive liner layers and compressive capping layers can be used alone or in combination to reduce and often eliminate cracking. Compressive capping layers in disclosed embodiments have additionally been determined to enable an underlying layer of silicon nitride to be transformed into a silicon oxide layer.