Abstract: Embodiments of methods and apparatus for removing particles from a surface of a substrate, such as from the backside of the substrate, are provided herein. In some embodiments, an apparatus for removing particles from a surface of a substrate includes: a substrate handler to expose the surface of the substrate; a particle separator to separate particles from the exposed surface of the substrate; a particle transporter to transport the separated particles; and a particle collector to collect the transported particles.

Abstract: The invention relates to a method of etching a layer of porous dielectric material, characterized in that the etching is performed in a plasma formed from at least one silicon-based gas mixed with oxygen (O2) and/or nitrogen (N2) so as to grow a passivation layer all along said etching, at least on flanks of the layer of porous dielectric material and wherein the silicon-based gas is taken from all the compounds of the type SixHy for which the ratio x/y is equal or greater than 0.3 or is taken from all the compounds of the following types: SixFy and SixCly, where x is the proportion of silicon (Si) in the gas and y is the proportion of fluorine (F) or chlorine (Cl) or hydrogen (H) in the gas.

Abstract: Semiconductor systems and methods may include methods of performing selective etches that include modifying a material on a semiconductor substrate. The substrate may have at least two exposed materials on a surface of the semiconductor substrate. The methods may include forming a low-power plasma within a processing chamber housing the semiconductor substrate. The low-power plasma may be a radio-frequency (“RF”) plasma, which may be at least partially formed by an RF bias power operating between about 10 W and about 100 W in embodiments. The RF bias power may also be pulsed at a frequency below about 5,000 Hz. The methods may also include etching one of the at least two exposed materials on the surface of the semiconductor substrate at a higher etch rate than a second of the at least two exposed materials on the surface of the semiconductor substrate.

Abstract: Methods of the disclosure include a BN ALD process at low temperatures using a reactive nitrogen precursor, such as thermal N2H4, and a boron containing precursor, which allows for the deposition of ultra thin (less than 5 nm) films with precise thickness and composition control. Methods are self-limiting and provide saturating atomic layer deposition (ALD) of a boron nitride (BN) layer on various semiconductors and metallic substrates.

Abstract: Semiconductor systems and methods may include methods of performing selective etches that include modifying a material on a semiconductor substrate. The substrate may have at least two exposed materials on a surface of the semiconductor substrate. The methods may include forming a low-power plasma within a processing chamber housing the semiconductor substrate. The low-power plasma may be a radio-frequency (“RF”) plasma, which may be at least partially formed by an RF bias power operating between about 10 W and about 100 W in embodiments. The RF bias power may also be pulsed at a frequency below about 5,000 Hz. The methods may also include etching one of the at least two exposed materials on the surface of the semiconductor substrate at a higher etch rate than a second of the at least two exposed materials on the surface of the semiconductor substrate.

Abstract: Semiconductor systems and methods may include methods of performing selective etches that include modifying a material on a semiconductor substrate. The substrate may have at least two exposed materials on a surface of the semiconductor substrate. The methods may include forming a low-power plasma within a processing chamber housing the semiconductor substrate. The low-power plasma may be a radio-frequency (“RF”) plasma, which may be at least partially formed by an RF bias power operating between about 10 W and about 100 W in embodiments. The RF bias power may also be pulsed at a frequency below about 5,000 Hz. The methods may also include etching one of the at least two exposed materials on the surface of the semiconductor substrate at a higher etch rate than a second of the at least two exposed materials on the surface of the semiconductor substrate.

Abstract: Methods and process chambers for etching of low-k and other dielectric films are described. For example, a method includes modifying portions of the low-k dielectric layer with a plasma process. The modified portions of the low-k dielectric layer are etched selectively over a mask layer and unmodified portions of the low-k dielectric layer. Etch chambers having multiple chamber regions for alternately generating distinct plasmas are described. In embodiments, a first charge coupled plasma source is provided to generate an ion flux to a workpiece in one operational mode, while a secondary plasma source is provided to provide reactive species flux without significant ion flux to the workpiece in another operational mode. A controller operates to cycle the operational modes repeatedly over time to remove a desired cumulative amount of the dielectric material.

Abstract: Methods and process chambers for etching of low-k and other dielectric films are described. For example, a method includes modifying portions of the low-k dielectric layer with a plasma process. The modified portions of the low-k dielectric layer are etched selectively over a mask layer and unmodified portions of the low-k dielectric layer. Etch chambers having multiple chamber regions for alternately generating distinct plasmas are described. In embodiments, a first charge coupled plasma source is provided to generate an ion flux to a workpiece in one operational mode, while a secondary plasma source is provided to provide reactive species flux without significant ion flux to the workpiece in another operational mode. A controller operates to cycle the operational modes repeatedly over time to remove a desired cumulative amount of the dielectric material.

Abstract: Embodiments include methods and systems of 3D structure fill. In one embodiment, a method of filling a trench in a wafer includes performing directional plasma treatment with an ion beam at an angle with respect to a sidewall of the trench to form a treated portion of the sidewall and an untreated bottom of the trench. A material is deposited in the trench. The deposition rate of the material on the treated portion of the sidewall is different than a second deposition rate on the untreated bottom of the trench. In one embodiment, a method includes depositing a material on the wafer, filling a bottom of the trench and forming a layer on a sidewall of the trench and a top surface adjacent to the trench. The method includes etching the layer with an ion beam at an angle with respect to the sidewall.

Abstract: A method is provided for forming spacers for a gate of a field effect transistor, the gate being situated above a layer of semiconductor material, including forming a layer of nitride covering the gate; modifying the layer by plasma implantation of light ions, having an atomic number equal or less than 10, in the layer in order to form a modified layer of nitride, the modifying being performed so as not to modify the layer of nitride over its entire thickness at flanks of the gate; and removing the modified layer of nitride by a selective wet or dry etching, of the modified layer relative to said layer of semiconductor material and relative to the non-modified layer at the flanks of the gate, without etching the layer of semiconductor material, wherein an entire length of the non-modified layer at the flanks remains after the selective wet or dry etching.

Abstract: Embodiments include methods and systems of 3D structure fill. In one embodiment, a method of filling a trench in a wafer includes performing directional plasma treatment with an ion beam at an angle with respect to a sidewall of the trench to form a treated portion of the sidewall and an untreated bottom of the trench. A material is deposited in the trench. The deposition rate of the material on the treated portion of the sidewall is different than a second deposition rate on the untreated bottom of the trench. In one embodiment, a method includes depositing a material on the wafer, filling a bottom of the trench and forming a layer on a sidewall of the trench and a top surface adjacent to the trench. The method includes etching the layer with an ion beam at an angle with respect to the sidewall.

Abstract: A method is provided for forming spacers for a gate of a field effect transistor, the gate being situated above a layer of semiconductor material, including forming a layer of nitride covering the gate; modifying the layer by plasma implantation of light ions, having an atomic number equal or less than 10, in the layer in order to form a modified layer of nitride, the modifying being performed so as not to modify the layer of nitride over its entire thickness at flanks of the gate; and removing the modified layer of nitride by a selective wet or dry etching, of the modified layer relative to said layer of semiconductor material and relative to the non-modified layer at the flanks of the gate, without etching the layer of semiconductor material, wherein an entire length of the non-modified layer at the flanks remains after the selective wet or dry etching.

Abstract: Methods of processing a substrate are provided herein. In some embodiments, a method of processing a substrate disposed in a processing chamber includes: (a) depositing a layer of material on a substrate by exposing the substrate to a first reactive species generated from a remote plasma source and to a first precursor, wherein the first reactive species reacts with the first precursor; and (b) treating all, or substantially all, of the deposited layer of material by exposing the substrate to a plasma generated within the processing chamber from a second plasma source; wherein at least one of the remote plasma source or the second plasma source is pulsed to control periods of depositing and periods of treating.

Abstract: An exemplary semiconductor processing system may include a remote plasma source coupled with a processing chamber having a top plate. An inlet assembly may be used to couple the remote plasma source with the top plate and may include a mounting assembly, which in embodiments may include at least two components. The inlet assembly may further include a precursor distribution assembly defining a plurality of distribution channels fluidly coupled with an injection port.

Abstract: An exemplary semiconductor processing system may include a remote plasma source coupled with a processing chamber having a top plate. An inlet assembly may be used to couple the remote plasma source with the top plate and may include a mounting assembly, which in embodiments may include at least two components. The inlet assembly may further include a precursor distribution assembly defining a plurality of distribution channels fluidly coupled with an injection port.

Abstract: A three-dimensional structure disposed on a substrate is processed so as to alter the etch rate of material disposed on at least one surface of the structure. In some embodiments, a conformal deposition of material is performed on the three-dimensional structure. Subsequently, an ion implant is performed on at least one surface of the three-dimensional structure. This ion implant serves to alter the etch rate of the material deposited on that structure. In some embodiments, the ion implant increases the etch rate of the material. In other embodiments, the ion implant decreases the etch rate. In some embodiments, ion implants are performed on more than one surface, such that the material on at least one surface is etched more quickly and material on at least one other surface is etched more slowly.

Abstract: An exemplary semiconductor processing system may include a high-frequency electrical source that has an outlet plug. The system may include a processing chamber having a top plate, and an inlet assembly coupled with the top plate. The inlet assembly may include an electrode defining an aperture at a first end and configured to receive the outlet plug. The aperture may be characterized at the first end by a first diameter, and a second end of the aperture opposite the first end may be characterized by a second diameter less than the first diameter. The inlet assembly may further include an inlet insulator coupled with the top plate and configured to electrically insulate the top plate from the electrode.

Abstract: An exemplary semiconductor processing system may include a processing chamber and a first plasma source. The first plasma source may utilize a first electrode positioned externally to the processing chamber, and the first plasma source may be configured to generate a first plasma. The processing system may further comprise a second plasma source separate from the first plasma source that utilizes a second electrode separate from the first electrode. The second electrode may be positioned externally to the processing chamber, and the second plasma source may be configured to generate a second plasma within the processing chamber. The processing system may further comprise a showerhead disposed between the relative locations of the first plasma electrode and the second plasma electrode.

Abstract: An exemplary semiconductor processing system may include a remote plasma source coupled with a processing chamber having a top plate. An inlet assembly may be used to couple the remote plasma source with the top plate and may include a mounting assembly, which in embodiments may include at least two components. The inlet assembly may further include a precursor distribution assembly defining a plurality of distribution channels fluidly coupled with an injection port.

Abstract: Embodiments involve patterned mask formation. In one embodiment, a method involves depositing a CVD film over a semiconductor wafer; exposing the CVD film to e-beam or UV radiation, forming a pattern in the CVD film; and etching the pattern in the CVD film, forming features in areas not exposed to the e-beam or UV radiation. In one embodiment, a method involves depositing a CVD film over a semiconductor wafer; depositing a thin photo-sensitive CVD hardmask film over the CVD film; exposing the thin photo-sensitive CVD hardmask film to e-beam or UV radiation, forming a pattern in the thin photo-sensitive CVD hardmask film; etching the pattern in the thin photo-sensitive CVD hardmask film; etching the pattern into the CVD film through the patterned thin photo-sensitive CVD hardmask film; and removing the patterned thin photo-sensitive CVD hardmask film.