Abstract: A method for plasma processing that includes: loading a dummy wafer between a focus ring positioned within a plasma process chamber; depositing a material layer over the focus ring by a plasma deposition process within the plasma process chamber; removing the dummy wafer from the plasma process chamber, and loading a substrate to be processed between the focus ring with the material layer within the plasma process chamber and performing a plasma process on the substrate.

Abstract: A method of microfabrication includes depositing a photoresist film on a working surface of a semiconductor wafer, the photoresist film being sensitive to extreme ultraviolet radiation; exposing the photoresist film to a pattern of extreme ultraviolet radiation; performing a hybrid develop of the photoresist film. The hybrid develop includes executing a first development process to remove a first portion of the photoresist film; stopping the development of the photoresist film after the first development process, the photo resist film including a structure having a first critical dimension larger than a target critical dimension after the stopping; and after stopping the development, executing a second development process to remove a second portion of the photoresist film and shrinking the critical dimension of the structure from the first critical dimension to a second critical dimension that is less than the first critical dimension.

Abstract: A method for fabricating a semiconductor device is described that includes forming a base layer over a top layer of a substrate, the base layer includes a silicon based dielectric having a thickness less than or equal to 5 nm and greater than or equal to 0.5 nm; forming a photoresist layer over the base layer, the photoresist including a first side and an opposite second side; exposing a first portion of the photoresist layer to a pattern of extreme ultraviolet (EUV) radiation from the first side; exposing a second portion of the photoresist layer with a pattern of electron flux from the second side, the electron flux being directed into the photoresist layer from the base layer in response to the EUV radiation; developing the exposed photoresist layer to form a patterned photoresist layer; and transferring the pattern of the patterned photoresist layer to the base layer and the top layer.

Abstract: Methods and improved process flows are provided herein for forming self-aligned contacts using spin-on silicon carbide (SiC). More specifically, the disclosed methods and process flows form self-aligned contacts by using spin-on SiC as a cap layer for at least one other structure, instead of depositing a SiC layer via plasma vapor deposition (PVD), chemical vapor deposition (CVD), atomic layer deposition (ALD), etc. The other structure may be a source and drain contact made through the use of a trench conductor. By utilizing spin-on SiC as a cap layer material, the disclosed methods and process flows avoid problems that typically occur when SiC is deposited, for example by CVD, and subsequently planarized. As such, the disclosed methods and process flows improve upon conventional methods and process flows for forming self-aligned contacts by reducing defectivity and improving yield.

Abstract: Methods and systems for selective deposition of conductive a cap for FAV features are described. In an embodiment, a method may include receiving a substrate having an interlayer dielectrics (ILD) layer, the ILD layer having a recess, the recess having a conductive layer formed therein, the conductive layer comprising a first conductive material. Additionally, such a method may include forming a cap within a region defined by the recess and in contact with a surface of the conductive layer, the cap comprising a second conductive material. The method may also include forming a conformal etch stop layer in contact with a surface of the cap and in contact with a region of the ILD layer. Further, the method may include selectively etching the etch stop layer using a plasma etch process, wherein the plasma etch process removes the etch stop layer selective to the second conductive material comprising the cap.

Abstract: Systems and methods are provided herein for etch features on a substrate, while maintaining a near-unity critical dimension (CD) shrink ratio. The features etched may include, but are not limited to contacts, vias, etc. More specifically, the techniques described herein use a pulsed plasma to control the polymer build-up ratio between the major CD and minor CD of the feature, and thus, control the CD shrink ratio when etching features having substantially different major and minor dimensions. The CD shrink ratio is controlled by selecting or adjusting one or more operational parameters (e.g., duty cycle, RF power, etch chemistry, etc.) of the plasma etch process(es) to control the amount of polymer build-up at the major and minor dimensions of the feature.

Abstract: Methods and improved process flows are provided herein for forming self-aligned contacts using spin-on silicon carbide (SiC). More specifically, the disclosed methods and process flows form self-aligned contacts by using spin-on SiC as a cap layer for at least one other structure, instead of depositing a SiC layer via plasma vapor deposition (PVD), chemical vapor deposition (CVD), atomic layer deposition (ALD), etc. The other structure may be a source and drain contact made through the use of a trench conductor. By utilizing spin-on SiC as a cap layer material, the disclosed methods and process flows avoid problems that typically occur when SiC is deposited, for example by CVD, and subsequently planarized. As such, the disclosed methods and process flows improve upon conventional methods and process flows for forming self-aligned contacts by reducing defectivity and improving yield.

Abstract: A substrate is provided with a patterned layer, such as, a photo resist layer which may exhibit line roughness. The patterned layer may be an EUV photo resist layer utilized in a self-aligned multi-patterning process. A tone inversion process having a tone inversion layer is utilized along with a surface treatment of a sidewall of the tone inversion layer so as to improve line roughness characteristics of the process. More specifically, a tone inversion layer may be patterned and then sidewalls of the tone inversion layer may be treated. A fill material may then be deposited upon the substrate including adjacent the sidewalls of the tone inversion layer. When the tone inversion layer is removed, the roughness of the fill material will be reduced due to the use of the sidewall treatment.

Abstract: A method is described for patterning a dielectric layer disposed over a semiconductor substrate layer. The patterning process includes forming a patterned hard mask layer over the dielectric layer, the patterned hard mask layer exposing a portion of a major surface of the dielectric layer. A portion of the dielectric layer is removed by a cyclic etch process, where performing one cycle of the cyclic etch process comprises forming a capping layer selectively over the patterned hard mask layer and performing a timed etch process that removes material from the dielectric layer. In another method, the deposition over the hard mask and the removal of the portion of the dielectric layer are performed concurrently.

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: Methods and improved process flows are provided herein for forming self-aligned contacts using spin-on silicon carbide (SiC). More specifically, the disclosed methods and process flows form self-aligned contacts by using spin-on SiC as a cap layer for at least one other structure, instead of depositing a SiC layer via plasma vapor deposition (PVD), chemical vapor deposition (CVD), atomic layer deposition (ALD), etc. The other structure may be a source and drain contact made through the use of a trench conductor. By utilizing spin-on SiC as a cap layer material, the disclosed methods and process flows avoid problems that typically occur when SiC is deposited, for example by CVD, and subsequently planarized. As such, the disclosed methods and process flows improve upon conventional methods and process flows for forming self-aligned contacts by reducing defectivity and improving yield.

Abstract: A method of plasma etching includes receiving, by a plasma processing apparatus, a substrate into a processing chamber of the plasma processing apparatus. The substrate includes an etchable layer and a first mask layer overlying the etchable layer. The first mask layer includes a plurality of openings vertically aligned with exposed regions of the etchable layer. The method further includes forming, in the processing chamber, a protective layer over the first mask layer and the exposed regions and etching, in the processing chamber, the protective layer and the exposed regions to remove the protective layer and form recesses in the etchable layer.

Abstract: A method is provided for self-aligned multi-patterning on a semiconductor workpiece using an integrated sequence of processing steps executed on a common manufacturing platform hosting one or more film-forming modules, one or more etching modules, and one or more transfer modules. A workpiece having a mandrel pattern formed thereon is received into the common manufacturing platform. A sidewall spacer pattern is formed based, at least in part, on the mandrel pattern, the sidewall spacer pattern having a plurality of second features separated by a second pitch distance with the first pitch distance being greater than the second pitch distance. The integrated sequence of processing steps is executed within the common manufacturing platform without leaving the controlled environment and the transfer modules are used to transfer the workpiece between the processing modules while maintaining the workpiece within the controlled environment. Broadly, forming a sidewall spacer pattern based on the mandrel pattern.

Abstract: A method for processing a substrate includes performing a first etch process to form a plurality of partial features in a dielectric layer disposed over the substrate; performing an irradiation process to irradiate the substrate with ultra-violet radiation having a wavelength between 100 nm and 200 nm; and after the irradiation process, performing a second etch process to form a plurality of features from the plurality of partial features.

Abstract: A method for forming a device includes forming a hole pattern in a resist layer disposed over a substrate. The substrate includes contact regions disposed over a major surface of the substrate and a dielectric layer disposed over the contact regions. The resist layer is disposed over the dielectric layer and the hole pattern includes through openings in the resist layer that are aligned with the contact regions. The through openings include a first through opening having a first critical dimension and a second through opening having a second critical dimension greater than the first critical dimension. The method includes modifying the hole pattern by depositing a material including silicon within the through openings by exposing the hole pattern to a first plasma generated from a gas mixture including SiCl4 and hydrogen, and then etching holes in the dielectric layer through the modified hole pattern, exposing the contact regions.

Abstract: In accordance with an embodiment, a method of plasma processing includes etching a refractory metal by flowing oxygen into a plasma processing chamber, intermittently flowing a passivation gas into the plasma processing chamber, and supplying power to sustain a plasma in the plasma processing chamber.

Abstract: A method for processing a substrate includes performing a first etch process to form a plurality of partial features in a dielectric layer disposed over the substrate; performing an irradiation process to irradiate the substrate with ultra-violet radiation having a wavelength between 100 nm and 200 nm; and after the irradiation process, performing a second etch process to form a plurality of features from the plurality of partial features.

Abstract: Improved process flows and methods are provided herein for trimming structures formed on a patterned substrate. In the disclosed process flows and methods, a self-aligned multiple patterning (SAMP) process is utilized for patterning structures, such as mandrels, on a substrate. After the structures are patterned, an atomic layer deposition (ALD) process is used to form a spacer layer on the patterned structures. In the SAMP process disclosed herein, a critical dimension (CD) of the patterned structures is trimmed concurrently with, and as a result of, the formation of the spacer layer by controlling various ALD process parameters and conditions. By trimming the patterned structures in situ of the ALD chamber used to form the spacer layer on the patterned structures, the improved process flows and methods described herein provide a CD trim method that does not adversely affect the pattern profile or process throughput.

Abstract: Improved methods are provided for transferring a photoresist pattern onto one or more underlying layers. In the disclosed embodiments, etch selectivity between a photoresist layer and one or more underlying layers is improved by pre-treating the underlying layer(s) with a plasma before the photoresist layer is deposited and patterned to form a photoresist pattern. The plasma modifies the underlying layer(s) by implanting ions into the underlying layer(s) to form a modified layer. When the modified layer is subsequently etched to transfer the photoresist pattern onto the modified layer, the presence of ions within the modified layer increases the etch rate of the modified layer, compared to the etch rate that the underlying layer(s) would have exhibited without plasma pre-treatment. The increased etch rate of the modified layer improves etch selectivity between the photoresist layer and the modified layer and mitigates defects during the photoresist pattern transfer process.

Abstract: Methods are disclosed that provide improved via profile control by forming atomic layer deposition (ALD) liners to protect side walls of vias during subsequent etch processes. ALD liners can be used for BEOL etch processes as well as for full self-aligned via (FSAV) processes and/or other processes. For one embodiment, ALD liners are used as protection or sacrificial layers for vias to reduce damage during multilayer via or trench etch processes. The ALD liners can also be deposited at different points within process flows, for example, before or after removal of organic planarization layers. The use of ALD liners facilitates shrinking of via critical dimensions (CDs) while still controlling via profiles for various process applications including dual Damascene processes and FSAV processes. In addition, the use of ALD liners improves overall CD control for via or hole formation as well as device yield and reliability.