Abstract: Embodiments of the invention generally provide a method of forming an air gap between conductive elements of a semiconductor device, wherein the air gap has a dielectric constant of approximately 1. The air gap may generally be formed by depositing a sacrificial material between the respective conductive elements, depositing a porous layer over the conductive elements and the sacrificial material, and then stripping the sacrificial material out of the space between the respective conductive elements through the porous layer, which leaves an air gap between the respective conductive elements. The sacrificial material may be, for example, a polymerized alpha terpinene layer, the porous layer may be, for example, a porous carbon doped oxide layer, and the stripping process may utilize a UV based curing process, for example.

Abstract: Methods are provided for forming a structure that includes an air gap. In one embodiment, a method is provided for forming a damascene structure comprises depositing a porous low dielectric constant layer by a method including reacting an organosilicon compound and a porogen-providing precursor, depositing a porogen-containing material, and removing at least a portion of the porogen-containing material, depositing an organic layer on the porous low dielectric constant layer by reacting the porogen-providing precursor, forming a feature definition in the organic layer and the porous low dielectric constant layer, filing the feature definition with a conductive material therein, depositing a mask layer on the organic layer and the conductive material disposed in the feature definition, forming apertures in the mask layer to expose the organic layer, removing a portion or all of the organic layer through the apertures, and forming an air gap adjacent the conductive material.

Abstract: A heater liner assembly suitable for covering the interior of a plasma processing chamber is provided. In some embodiments, a liner assembly for a processing chamber can include a heating element embedded in a body. A flange extending outward from an outer diameter of the body includes an upper surface having a sealing surface and at least one pad that extends from the upper surface of the flange to an elevation beyond the sealing surface. The pad contributes to control of the temperature of the liner assembly by maintaining the liner assembly spaced apart from the processing chamber.

Abstract: A method of forming a cap layer over a dielecrtic layer on a substrate including forming a plasma from a process gas including oxygen and tetraethoxysilane, and depositing the cap layer on the dielectric layer, where the cap layer comprises a thickness of about 600 ? or less, and a compressive stress of about 200 MPa or more. Also, a method of forming a cap layer over a dielectric layer on a substrate including forming a process gas by flowing together about 200 mgm to about 8000 mgm of tetraethoxysilane, about 2000 to about 20000 sccm of oxygen (O2), and about 2000 sccm to about 20000 sccm of carrier gas, generating a plasma from the process gas, where one or more RF generators supply about 50 watts to about 100 watts of low frequency RF power to the plasma, and about 100 watts to about 600 watts of high frequency RF power to the plasma, and depositing the cap layer on the dielectric layer.

Abstract: A method for depositing an amorphous carbon layer on a substrate includes the steps of positioning a substrate in a chamber, introducing a hydrocarbon source into the processing chamber, introducing a heavy noble gas into the processing chamber, and generating a plasma in the processing chamber. The heavy noble gas is selected from the group consisting of argon, krypton, xenon, and combinations thereof and the molar flow rate of the noble gas is greater than the molar flow rate of the hydrocarbon source. A post-deposition termination step may be included, wherein the flow of the hydrocarbon source and the noble gas is stopped and a plasma is maintained in the chamber for a period of time to remove particles therefrom.

Abstract: Unwanted hillocks arising in copper layers due to formation of overlying barrier layers may be significantly reduced by optimizing various process parameters, alone or in combination. A first set of process parameters may be controlled to pre-condition the processing chamber in which the barrier layer is deposited. A second set of process parameters may be controlled to minimize energy to which a copper layer is exposed during removal of CuO prior to barrier deposition. A third set of process parameters may be controlled to minimize the thermal budget after removal of the copper oxide.

Abstract: The present invention generally provides an apparatus and method for reducing defects on films deposited on semiconductor substrates. One embodiment of the present invention provides a method for depositing a film on a substrate. The method comprises treating the substrate with a first plasma configured to reduce pre-existing defects on the substrate, and depositing a film comprising silicon and carbon on the substrate by applying a second plasma generated from at least one precursor and at least one reactant gas.

Abstract: Methods for reducing plasma instability for plasma depositing a dielectric layer are provided. In one embodiment, the method includes providing a substrate in a plasma processing chamber, flowing a gas mixture into the chamber, applying an RF power to an electrode to form a plasma in the chamber, and collecting DC bias information. In another embodiment, the method for plasma processing includes obtaining of DC bias information over a plurality of plasma generation events, and determining an RF power application parameter from the DC bias information.

Abstract: A method for depositing an amorphous carbon layer on a substrate includes the steps of positioning a substrate in a chamber, introducing a hydrocarbon source into the processing chamber, introducing a heavy noble gas into the processing chamber, and generating a plasma in the processing chamber. The heavy noble gas is selected from the group consisting of argon, krypton, xenon, and combinations thereof and the molar flow rate of the noble gas is greater than the molar flow rate of the hydrocarbon source. A post-deposition termination step may be included, wherein the flow of the hydrocarbon source and the noble gas is stopped and a plasma is maintained in the chamber for a period of time to remove particles therefrom.

Abstract: Methods for low temperature deposition an amorphous carbon film with improved step coverage are provided. In one embodiment, the method includes providing a substrate in a process chamber, flowing a gas mixture including at least a hydrocarbon compound and an inert gas into the process chamber, wherein the hydrocarbon compound has greater than 5 carbon atoms, maintaining the substrate temperature at a range below 450 degrees Celsius, and depositing an amorphous carbon film on the substrate.

Abstract: The present invention generally provides an apparatus and method for eliminating the “first wafer effect” for plasma enhanced chemical vapor deposition (PECVD). One embodiment of the present invention provides a method for preparing a chamber after the chamber being idle for a period of time. The method comprises a cleaning step followed by a season step and a heating step adapted to the length of the idle time.

Abstract: Methods and apparatus are provided for processing a substrate with a hermetic dielectric layer. In one aspect, the invention provides a method for processing a substrate including providing the substrate to a processing chamber, introducing a processing gas comprising a reducing agent, an oxygen containing compound, and an organosilicon compound, into the processing chamber, generating a plasma from a dual frequency RF power source, and depositing a dielectric material comprising silicon, carbon, and oxygen. The dielectric material may be used as an etch stop, an anti-reflective coating, or a passivation layer.

Abstract: A method of forming a cap layer over a dielectric layer on a substrate including forming a plasma from a process gas including oxygen and tetraethoxysilane, and depositing the cap layer on the dielectric layer, where the cap layer comprises a thickness of about 600 ? or less, and a compressive stress of about 200 MPa or more. Also, a method of forming a cap layer over a dielectric layer on a substrate including forming a process gas by flowing together about 200 mgm to about 8000 mgm of tetraethoxysilane, about 2000 to about 20000 sccm of oxygen (O2), and about 2000 sccm to about 20000 sccm of carrier gas, generating a plasma from the process gas, where one or more RF generators supply about 50 watts to about 100 watts of low frequency RF power to the plasma, and about 100 watts to about 600 watts of high frequency RF power to the plasma, and depositing the cap layer on the dielectric layer.

Abstract: A method of processing a substrate including depositing a low dielectric constant film comprising silicon, carbon, and oxygen on the substrate and depositing an oxide rich cap on the low dielectric constant film is provided. The low dielectric constant film is deposited in the presence of low frequency RF power from a gas mixture including an organosilicon compound and an oxidizing gas. The low frequency RF power is terminated after the deposition of the low dielectric constant film. The oxide rich cap is deposited on the low dielectric constant film in the absence of low frequency RF power from another gas mixture including the organosilicon compound and the oxidizing gas used to deposit the low dielectric constant film.

Abstract: A method of depositing a organosilicate dielectric layer exhibiting high adhesion strength to an underlying substrate disposed within a single processing chamber without plasma arcing. The method includes positioning a substrate within a processing chamber having a powered electrode, flowing an interface gas mixture into the processing chamber, the interface gas mixture comprising one or more organosilicon compounds and one or more oxidizing gases, depositing a silicon oxide layer on the substrate by varying process conditions, wherein DC bias of the powered electrode varies less than 60 volts.

Abstract: A method of processing a substrate including depositing a transition layer and a dielectric layer on a substrate in a processing chamber are provided. The transition layer is deposited from a processing gas including an organosilicon compound and an oxidizing gas. The flow rate of the organosilicon compound is ramped up during the deposition of the transition layer such that the transition layer has a carbon concentration gradient and an oxygen concentration gradient. The transition layer improves the adhesion of the dielectric layer to an underlying barrier layer on the substrate.

Abstract: Methods and systems of diagnosing an arcing problem in a semiconductor wafer processing chamber are described. The methods may include coupling a voltage probe to a process-gas distribution faceplate in the processing chamber, and activating an RF power source to generate a plasma between the faceplate and a substrate wafer. The methods may also include measuring the DC bias voltage of the faceplate as a function of time during the activation of the RF power source, where a spike in the measured voltage at the faceplate indicates an arcing event has occurred in the processing chamber. Methods and systems to reduce arcing in a semiconductor wafer processing chamber are also described.

Abstract: Methods are provided for depositing a dielectric material. The dielectric material may be used for an anti-reflective coating or as a hardmask. In one aspect, a method is provided for processing a substrate including introducing a processing gas comprising a silane-based compound and an organosilicon compound to the processing chamber and reacting the processing gas to deposit a nitrogen-free dielectric material on the substrate. The dielectric material comprises silicon and oxygen.

Abstract: Methods and apparatus are provided for processing a substrate with a bilayer barrier layer. In one aspect, the invention provides a method for processing a substrate including depositing a nitrogen containing barrier layer on a substrate surface and then depositing a nitrogen free barrier layer thereon. The barrier layer may be deposited over dielectric materials, conductive materials, or both. The bilayer barrier layer may also be used as an etch stop, an anti-reflective coating, or a passivation layer.

Abstract: A porous dielectric film for use in electronic devices is disclosed that is formed by removal of soluble nano phase porogens. A silicon based dielectric film having soluble porogens dispersed therein is prepared by chemical vapor deposition (CVD) or by spin on glass (S.O.G.). Examples of preferable porogens include compounds such as germanium oxide (GeO2) and boron oxide (B2O3). Hot water can be used in processing to wet etch the film, thereby removing the porogens and providing the porous dielectric film. The silicon based dielectric film may be a carbon doped silicon oxide in order to further reduce the dielectric constant of the film. Additionally, the porous dielectric film may be treated by an electron beam to enhance the electrical and mechanical properties of the film.