Abstract: Interlayer dielectric gap fill processes are enhanced by forming gate spacers with a tapered profile. Embodiments include forming a gate electrode on a substrate, depositing a spacer material over the gate electrode and substrate, the spacer layer having a first surface nearest the gate electrode and substrate, a second surface furthest from the gate electrode and substrate, and a continuously increasing etch rate from the first surface to the second surface, and etching the spacer layer to form a spacer on each side of the gate electrode. Embodiments further include forming the spacer layer by depositing a spacer material and continuously decreasing the density of the spacer material during deposition or depositing a carbon-containing spacer material and causing a gradient of carbon content in the spacer layer.

Abstract: Methods of deducing oxide thickness using calculated and measured scattering spectra are provided. Embodiments include depositing an oxide over a semiconductor wafer, reducing the oxide from a portion of the semiconductor wafer, and deducing a thickness of oxide remaining at a location within the portion using scatterometric metrology. Embodiments further include deducing the thickness by: calculating scattering spectra for a plurality of oxide thicknesses, producing calculated scattering spectra, monitoring scattering spectra at the location within the portion of the semiconductor wafer, comparing the monitored scattering spectra at the location to the calculated scattering spectra, determining a closest matching calculated scattering spectra to the monitored scattering spectra at the location, and obtaining an oxide thickness corresponding to the closest matching calculated scattering spectra.

Abstract: A device and methods for forming the device are disclosed. The method includes providing a substrate. A gate having a gate electrode and sidewall spacers are formed adjacent to sidewalls of the gate. A height HG of the gate is lower than a height HS of the sidewall spacers. A metal or metal alloy layer is deposited over the spacers, gate and the substrate. The substrate is processed to form metal silicide contact at least over the gate electrode. A top surface of the metal silicide contact over the gate electrode is about coplanar with a top of the sidewall spacer, and the difference between the height of the gate and spacers prevent formation of metal silicide filaments on top of the sidewall spacers.

Abstract: A copper layer is formed without copper hillocks. Embodiments includes providing a copper layer above a substrate, planarizing the copper layer, performing hydrogen (H2) plasma treatment on the copper layer in a first chamber, and forming a barrier layer over the copper layer in a second chamber, different from the first chamber.

Abstract: A method includes providing a substrate with a patterned second layer over a first layer. The second layer includes a second layer opening having a first CD equal to the CD produced by a lithographic system (CDL). CDL is larger than a desired CD (CDD). A third layer is formed to fill the opening, leaving a top surface of the second layer exposed. The second layer is removed to produce a mesa formed by the third layer. The CD of the mesa is equal to about the first CD. The mesa is trimmed to produce a mesa with a second CD equal to about CDD. A fourth layer is formed to cover the first layer, leaving a top of the mesa exposed. The substrate is etched to remove the mesa and a portion of the first layer below the mesa to form an opening in the first layer with CDD.

Abstract: A method and a device are provided for diffracting incident light from a lithographic scanner in an IC process flow. Embodiments include forming a diffraction grating in a first layer on a semiconductor substrate; and forming a plurality of lithographic alignment marks in a second layer, overlying the first layer, wherein the diffraction grating has a width and a length greater than or equal to a width and length, respectively, of the plurality of lithographic alignment marks.

Abstract: Semiconductor devices with through silicon vias (TSVs) are formed without copper contamination. Embodiments include exposing a passivation layer surrounding a bottom portion of a TSV in a silicon substrate, forming a silicon composite layer over the exposed passivation layer and over a bottom surface of the silicon substrate, forming a hardmask layer over the silicon composite layer and over the bottom surface of the silicon substrate, removing a section of the silicon composite layer around the bottom portion of the TSV using the hardmask layer as a mask, re-exposing the passivation layer, and removing the hardmask layer and the re-exposed passivation layer to expose a contact for the bottom portion of the TSV.

Abstract: An automated method for co-optimizing a scatterometry mark and a process monitoring mark is provided. Embodiments include generating a series of pattern profiles on a photoresist on a wafer; providing the series of pattern profiles, resist process parameters, and scatterometry critical dimension parameters as inputs for a scatterometry measurement; performing scatterometry measurement to generate spectra from the series of pattern profiles; and optimizing a sensitivity precision correlation for the resist process parameter.

Abstract: An optical proximity correction (OPC) model incorporates inline process variation data. OPC is performed by adjusting an input mask pattern with a mask bias derived from the OPC model to correct errors in the input mask pattern.

Abstract: A memory device is fabricated through the integration of embedded non-volatile memory (eNVM) with replacement metal gate (RMG) and high-k/metal gate (HKMG) modules. Embodiments include forming two substrate portions having upper surfaces at different heights, forming non-volatile gate stacks over the substrate portion with the lower upper surface, and forming high-voltage gate stacks and logic gate stacks over the other substrate portion. Embodiments include the upper surfaces of the non-voltage gate stacks, the high-voltage gate stacks, and the logic gate stacks being substantially coplanar.

Abstract: Interlayer dielectric gap fill processes are enhanced by forming gate spacers with a tapered profile. Embodiments include forming a gate electrode on a substrate, depositing a spacer material over the gate electrode and substrate, the spacer layer having a first surface nearest the gate electrode and substrate, a second surface furthest from the gate electrode and substrate, and a continuously increasing etch rate from the first surface to the second surface, and etching the spacer layer to form a spacer on each side of the gate electrode. Embodiments further include forming the spacer layer by depositing a spacer material and continuously decreasing the density of the spacer material during deposition or depositing a carbon-containing spacer material and causing a gradient of carbon content in the spacer layer.

Abstract: Interlayer dielectric gap fill processes are enhanced by forming gate spacers with a step-like or tapered profile. Embodiments include forming a gate electrode on a substrate, depositing a spacer material over the gate electrode, etching the spacer material to form a first spacer on each side of the gate electrode, and pulling back the first spacers to form second spacers which have a step-like profile. Embodiments further include depositing a second spacer material over the gate electrode and the second spacers, and etching the second spacer material to form a third spacer on each second spacer, the second and third spacers forming an outwardly tapered composite spacer.

Abstract: Interlayer dielectric gap fill processes are enhanced by forming gate spacers with a step-like or tapered profile. Embodiments include forming a gate electrode on a substrate, depositing a spacer material over the gate electrode, etching the spacer material to form a first spacer on each side of the gate electrode, and pulling back the first spacers to form second spacers which have a step-like profile. Embodiments further include depositing a second spacer material over the gate electrode and the second spacers, and etching the second spacer material to form a third spacer on each second spacer, the second and third spacers forming an outwardly tapered composite spacer.

Abstract: A memory device is fabricated through the integration of embedded non-volatile memory (eNVM) with replacement metal gate (RMG) and high-k/metal gate (HKMG) modules. Embodiments include forming two substrate portions having upper surfaces at different heights, forming non-volatile gate stacks over the substrate portion with the lower upper surface, and forming high-voltage gate stacks and logic gate stacks over the other substrate portion. Embodiments include the upper surfaces of the non-voltage gate stacks, the high-voltage gate stacks, and the logic gate stacks being substantially coplanar.

Abstract: An LED lamp includes a lamp body, a pair of holders received in the lamp body, a circuit board with a number of LEDs, and a pair of connectors. The circuit board is received in the lamp body but spaced from insides of the lamp body. The opposite ends of the circuit board are fixed to the holders correspondingly. The connectors are fixed to the holders and abut against opposite ends of the lamp body.

Abstract: A method for assessing metrology tool accuracy is described. Multi-variable regression is used to define the accuracy of a metrology tool such that the interaction between different measurement parameters is taken into account. A metrology tool under test (MTUT) and a reference metrology tool (RMT) are used to measure a set of test profiles. The MTUT measures the test profiles to generate a MTUT data set for a first measurement parameter. The RMT measures the test profiles to generate RMT data sets for the first measurement parameter, and at least a second measurement parameter. Multi-variable regression is then performed to generate a best-fit plane for the data sets. The coefficient of determination (R2 value) represents the accuracy index of the MTUT.

Abstract: A method for assessing metrology tool accuracy is described. Multi-variable regression is used to define the accuracy of a metrology tool such that the interaction between different measurement parameters is taken into account. A metrology tool under test (MTUT) and a reference metrology tool (RMT) are used to measure a set of test profiles. The MTUT measures the test profiles to generate a MTUT data set for a first measurement parameter. The RMT measures the test profiles to generate RMT data sets for the first measurement parameter, and at least a second measurement parameter. Multi-variable regression is then performed to generate a best-fit plane for the data sets. The coefficient of determination (R2 value) represents the accuracy index of the MTUT.

Abstract: An optical proximity correction (OPC) model incorporates inline process variation data. OPC is performed by adjusting an input mask pattern with a mask bias derived from the OPC model to correct errors in the input mask pattern.

Abstract: A multi-zone carrier head includes a housing; a retaining ring secured to a lower edge of the housing; a backing plate having a plurality of non-concentric pressure zones defined by a plurality of isolated apertures on the backing plate; wherein the backing plate has a wafer side and a non-wafer side, the wafer side facing a backside of a wafer during a CMP operation; and a plurality of pneumatic bladder for independently controlling pressure exerted in the respective non-concentric pressure zones on the backside of the wafer during the CMP operation.

Abstract: A patterned and etched layer of gate electrode material is formed over the active surface of a substrate, a layer of liner oxide is created, gate spacers are created. Under the first embodiment of the invention, a layer of TEOS is deposited over the created structure over which a layer of nitride is deposited, The layer of nitride is etched, this etch is extended into an overetch creating openings through the layer of TEOS where this layer overlies the gate spacers. The gate spacers are then further etched. Under the second embodiment of the invention, a layer of TEOS is deposited over the created structure. The layer of TEOS is etched, stopping on the silicon nitride of the gate spacers. The gate spacers are then further etched.