Abstract: A method for the via etching steps of a substrate manufacturing process flow is provided. The substrate processing techniques described provide for etching vias by providing a protection layer on the via sidewall during at least portions of the via etching process. In one embodiment, an atomic layer deposition (ALD) layer is formed on the via sidewalls to protect the dielectric layers through which the via is formed. The ALD layer may lessen bowing effects in low k dielectric layers which may result from etching barrier low k (blok) layers or from other process steps. After via formation, the ALD layer may be removed. The techniques are particularly suited for forming skip vias and other high aspect ratio vias formed in low k and ultra-low k dielectric layers.

Abstract: In certain embodiments, a method of forming a semiconductor device includes forming a patterned resist layer over a hard mask layer using an extreme ultraviolet (EUV) lithography process. The hard mask layer is disposed over a substrate. The method includes patterning the hard mask layer using the patterned resist layer as an etch mask. The method includes smoothing the hard mask layer by forming, using a first atomic layer etch step, a first layer by converting a first portion of the hard mask layer, and by removing, using a second atomic layer etch step, the first layer.

Abstract: A method of forming a device includes depositing a first etch mask layer over a mandrel formed using a lithography process. The method includes depositing a second etch mask layer over the first etch mask layer. The method includes, using a first anisotropic etching process, etching the first etch mask layer and the second etch mask layer to form an etch mask including the first etch mask layer and the second etch mask layer. The method includes removing the mandrel to expose an underlying surface of the layer to be patterned. The method includes, using the etch mask, forming a feature by performing a second anisotropic etching process to pattern the layer to be patterned, where during the first anisotropic etching process, the first etch mask layer etches at a first rate and the second etch mask layer etches at a second rate, and where the first rate is different from the second rate.

Abstract: A method of patterning a substrate includes receiving a substrate having microfabricated structures, including mandrels; executing a deposition process that deposits a first material on the mandrels, the deposition process including cyclically moving the substrate through a set of deposition modules. The substrate is moved through the set of deposition modules so that the first material is deposited at a first thickness at top portions of the mandrels and at a second thickness at bottom portions of mandrels, the first thickness being greater than the second thickness. The method includes executing a spacer deposition process that conformally deposits a second material on the substrate; executing a spacer open etch that removes depositions of the second material from over a top surface of the mandrels; removing the first material and the mandrels from the substrate, leaving sidewall spacers; and transferring a pattern defined by the sidewall spacers into an underlying layer.

Abstract: A method of patterning a substrate includes receiving a substrate having microfabricated structures, including mandrels; executing a deposition process that deposits a first material on the mandrels, the deposition process including cyclically moving the substrate through a set of deposition modules. The substrate is moved through the set of deposition modules so that the first material is deposited at a first thickness at top portions of the mandrels and at a second thickness at bottom portions of mandrels, the first thickness being greater than the second thickness. The method includes executing a spacer deposition process that conformally deposits a second material on the substrate; executing a spacer open etch that removes depositions of the second material from over a top surface of the mandrels; removing the first material and the mandrels from the substrate, leaving sidewall spacers; and transferring a pattern defined by the sidewall spacers into an underlying layer.

Abstract: Embodiments are described herein that apply capping layers to cores prior to spacer formation in self-aligned multiple patterning (SAMP) processes to achieve vertical spacer profiles. For one embodiment, a plasma process is used to deposit a capping layer on cores, and this capping layer causes resulting core profiles to have protective caps. These protective caps formed with the additional capping layer help to reduce or minimize material loss and corner loss of the core material during spacer deposition and spacer etch processes. This reduction in core material loss improves the resulting spacer profile so that a more vertical profile is achieved. For one embodiment, an angle of 80-90 degrees is achieved for vertical sidewalls of the spacers adjacent core sites with respect to the horizontal surface of the underlying layer, such as a hard mask layer formed on a substrate for a microelectronic workpiece.

Abstract: Methods and systems for line cut by multi-color patterning techniques are presented. In an embodiment, a method may include providing a substrate. The method may also include forming a first feature on the substrate, the first feature having a cap formed of a first material. Additionally, the method may include forming a second feature on the substrate, the second feature having a cap formed of a second material. In still a further embodiment, the method may include selectively removing the second feature using an etch process that etches the first material at a first etch rate and etches the second material at a second etch rate, wherein the second etch rate is higher than the first etch rate.

Abstract: Embodiments are disclosed for processing microelectronic workpieces to apply stress engineering to self-aligned multi-patterning (SAMP) processes. The disclosed processing methods utilize stress in a substrate in a SAMP process to improve resulting pattern parameters. Initially, a high stress film is deposited on the frontside and the backside of the substrate, and the high stress film provides biaxial stress to the substrate due to the deposition process for the high stress film. Next, a SAMP process is performed to form spacers in a spacer pattern. This spacer pattern is then transferred to underlying layers to form a patterned structure. The high stress film provides axial stress in at least one direction along a portion of the patterned structure during the pattern transfer thereby improving resulting pattern formation.

Abstract: A method is provided for void-free Ru metal filling of features in a substrate. The method includes providing a substrate containing features, depositing a Ru metal layer in the features, removing the Ru metal layer from a field area around an opening of the features, and depositing additional Ru metal in the features, where the additional Ru metal is deposited in the features at a higher rate than on the field area. According to one embodiment, the additional Ru metal is deposited until the features are fully filled with Ru metal.

Abstract: This disclosure relates to a high volume manufacturing system for processing and measuring workpieces in a semiconductor processing sequence without leaving the system's controlled environment (e.g., sub-atmospheric pressure). The systems process chambers are connected to each other via transfer chambers used to move the workpieces, in the controlled environment, between the process chambers. The transfer chambers include a measurement region with dedicated workpiece support chucks capable of translating and/or rotating the workpiece during the measurement.

Abstract: Embodiments are described herein to reduce formation of undesired particles during plasma processing for microelectronic workpieces by depositing a layer (e.g., think film) on the surface of a chuck, such as an electrostatic chuck (ESC), prior to plasma processing such as a plasma etch process (e.g., a reactive ion etch (RIE) process) and/or a plasma deposition process. This layer works as a lubricant or protective coating to reduce or minimize physical contact between the microelectronic workpiece (e.g., semiconductor wafer) and the chuck. This reduction in physical contact reduces scratching of the backside of the microelectronic workpiece and reduces related formation of undesired particles that can be transported to the front side of the microelectronic workpiece and cause defects and reduce yields. As such, the disclosed embodiments improve particle (PA) performance parameters for plasma etch and/or deposition processes.

Abstract: This disclosure relates to a high volume manufacturing system for processing and measuring workpieces in a semiconductor processing sequence without leaving the system's controlled environment (e.g., sub-atmospheric pressure). The systems process chambers are connected to each other via transfer chambers used to move the workpieces, in the controlled environment, between the process chambers. Further, the pass-through chambers may be disposed between the transfer chambers or between the transfer chamber and the process chamber. The pass-through chambers may include a measurement region to measure workpiece attributes when the workpiece is moved through or placed in the pass-through chamber. The transfer chambers may also have separate measurement regions within their internal space to measure other attributes of the workpiece.

Abstract: Methods and systems for in-situ spacer reshaping for self-aligned multi-patterning are described. In an embodiment, a method of forming a spacer pattern on a substrate may include providing a substrate with a spacer. The method may also include performing a passivation treatment to form a passivation layer on the spacer. Additionally, the method may include performing spacer reshaping treatment to reshape the spacer. The method may also include controlling the passivation treatment and spacer reshaping treatment in order to achieve spacer formation objectives.

Abstract: Methods and systems for line cut by multi-color patterning techniques are presented. In an embodiment, a method may include providing a substrate. The method may also include forming a first feature on the substrate, the first feature having a cap formed of a first material. Additionally, the method may include forming a second feature on the substrate, the second feature having a cap formed of a second material. In still a further embodiment, the method may include selectively removing the second feature using an etch process that etches the first material at a first etch rate and etches the second material at a second etch rate, wherein the second etch rate is higher than the first etch rate.

Abstract: Embodiments are disclosed for processing microelectronic workpieces to apply stress engineering to self-aligned multi-patterning (SAMP) processes. The disclosed processing methods utilize stress in a substrate in a SAMP process to improve resulting pattern parameters. Initially, a high stress film is deposited on the frontside and the backside of the substrate, and the high stress film provides biaxial stress to the substrate due to the deposition process for the high stress film. Next, a SAMP process is performed to form spacers in a spacer pattern. This spacer pattern is then transferred to underlying layers to form a patterned structure. The high stress film provides axial stress in at least one direction along a portion of the patterned structure during the pattern transfer thereby improving resulting pattern formation.

Abstract: A method for the via etching steps of a substrate manufacturing process flow is provided. The substrate processing techniques described provide for etching vias by providing a protection layer on the via sidewall during at least portions of the via etching process. In one embodiment, an atomic layer deposition (ALD) layer is formed on the via sidewalls to protect the dielectric layers through which the via is formed. The ALD layer may lessen bowing effects in low k dielectric layers which may result from etching barrier low k (blok) layers or from other process steps. After via formation, the ALD layer may be removed. The techniques are particularly suited for forming skip vias and other high aspect ratio vias formed in low k and ultra-low k dielectric layers.

Abstract: A method is provided for void-free Ru metal filling of features in a substrate. The method includes providing a substrate containing features, depositing a Ru metal layer in the features, removing the Ru metal layer from a field area around an opening of the features, and depositing additional Ru metal in the features, where the additional Ru metal is deposited in the features at a higher rate than on the field area. According to one embodiment, the additional Ru metal is deposited until the features are fully filled with Ru metal.

Abstract: Embodiments of systems and methods for spacer formation for SAMP techniques are described. In an embodiment a method includes providing a substrate with a spacer having a conformal coating. The method may also include performing a spacer freeze treatment process. Additionally, the method may include performing an etch and clean process on the substrate. Further, the method may include controlling the spacer treatment process and etch and clean process in order to achieve spacer formation objectives.

Abstract: An additional non-photoresist layer may be formed on patterned photoresist layers. The additional layer may be preferentially formed on the tops of the photoresist layer versus the sidewalls of the photoresist layer. In addition, the additional layer may be preferential formed on the tops of the photoresist layer versus exposed surfaces of layers underlying the photoresist layer. In this manner, the patterned structures formed by the photoresist layer are less likely to have line opens due to photoresist height variability or the relative thinness of the photoresist height used. Further, the formation of the additional layer may be through a cyclic deposition/trim process. The trim step of the cyclic process may also serve as a descum step that helps reduce line bridging and scumming. In one embodiment, the additional non-photoresist layer may be an organic polymer layer.

Abstract: Techniques herein include methods of processing photoresist patterns and photoresist materials for successful use in multi-patterning operations. Techniques include combinations of targeted deposition, curing, and trimming to provide a post-processed resist that effectively enables multi-patterning using photoresist materials to function as mandrels. Photoresist patterns and mandrels are hardened, strengthened, and/or dimensionally adjusted to provide desired dimensions and/or mandrels enabling straight sidewall spacers. Polymer is deposited with tapered profile to compensate for compressive stresses of various conformal or subsequent films to result in a vertical profile despite any compression.