Abstract: An integrated in situ etch process performed in a multichamber substrate processing system having first and second etching chambers. In one embodiment the first chamber includes an interior surface that has been roughened to at least 100 Ra and the second chamber includes an interior surface that has a roughness of less than about 32 Ra. The process includes transferring a substrate having formed thereon in a downward direction a patterned photoresist mask, a dielectric layer, a barrier layer and a feature in the substrate to be contacted into the first chamber where the dielectric layer is etched in a process that encourages polymer formation over the roughened interior surface of the chamber. The substrate is then transferred from the first chamber to the second chamber under vacuum conditions and, in the second chamber, is exposed to a reactive plasma such as oxygen to strip away the photoresist mask deposited over the substrate.

Abstract: A method is provided for etching a dielectric structure. The dielectric structure comprises: (a) a layer of undoped silicon oxide or F-doped silicon oxide; and (b) a layer of C,H-doped silicon oxide. The dielectric structure is etched in a plasma-etching step, which plasma-etching step is conducted using a plasma source gas that comprises nitrogen atoms and fluorine atoms. As one example, the plasma source gas can comprise a gaseous species that comprises one or more nitrogen atoms and one or more fluorine atoms (e.g., NF3). As another example, the plasma source gas can comprise (a) a gaseous species that comprises one or more nitrogen atoms (e.g., N2) and (b) a gaseous species that comprises one or more fluorine atoms (e.g., a fluorocarbon gas such as CF4). In this etching step, the layer of C,H-doped silicon oxide is preferentially etched relative to the layer of undoped silicon oxide or F-doped silicon oxide. The method of the present invention is applicable, for example, to dual damascene structures.

Abstract: The present invention provides a low-k dielectric etching process with high etching selectivities with respect to adjacent layers of other materials, such as an overlying photoresist mask and an underlying barrier/liner layer. The process comprises the step of exposing a portion of the low-k dielectric layer to a plasma of a process gas that includes a fluorocarbon gas, a nitrogen-containing gas, and an inert gas, wherein the volumetric flow ratio of inert:fluorocarbon gas is in the range of 20:1 to 100:1, and the volumetric flow ratio of fluorocarbon:nitrogen-containing gas is selected to provide a low-k dielectric to photoresist etching selectivity ratio greater than about 5:1 and a low-k dielectric etch rate higher than about 4000 ?/min.

Abstract: The present invention provides a novel etching technique for etching a layer of C-doped silicon oxide, such as a partially oxidized organo silane material. This technique, employing CH2F2/Ar chemistry at low bias and low to intermediate pressure, provides high etch selectivity to silicon oxide and improved selectivity to organic photoresist. Structures including a layer of partially oxidized organo silane material (1004) deposited on a layer of silicon oxide (1002) were etched according to the novel technique, forming relatively narrow trenches (1010, 1012, 1014, 1016, 1030, 1032, 1034 and 1036) and wider trenches (1020, 1022, 1040 and 1042). The technique is also suitable for forming dual damascene structures (1152, 1154 and 1156). In additional embodiments, manufacturing systems (1410) are provided for fabricating IC structures of the present invention. These systems include a controller (1400) that is adapted for interacting with a plurality of fabricating stations (1420, 1422, 1424, 1426 and 1428).

Abstract: Method, materials and structures are described for the fabrication of dual damascene features in integrated circuits. In via-first dual damascene fabrication, a bottom-antireflective-coating (“BARC”) is commonly deposited into the via and field regions surrounding the via, 107. Subsequent trench etch with conventional etching chemistries typically results in isolated regions of BARC, 107a, surrounded by “fencing” material, 108, at the bottom of the via. Such fencing hinders conformal coating with barrier/adhesion layers and can reduce device yield. The present invention relates to the formation of a BARC plug, 107c, partially filling the via and having a convex upper surface, 400, prior to etching the trench. Such a BARC structure is shown to lead to etching without the formation of fencing and a clean dual damascene structure for subsequent coating.

Abstract: The present invention provides a low-k dielectric etching process with high etching selectivities with respect to adjacent layers of other materials, such as an overlying photoresist mask and an underlying barrier/liner layer. The process comprises the step of exposing a portion of the low-k dielectric layer to a plasma of a process gas that includes a fluorocarbon gas, a nitrogen-containing gas, and an inert gas, wherein the volumetric flow ratio of inert:fluorocarbon gas is in the range of 20:1 to 100:1, and the volumetric flow ratio of fluorocarbon:nitrogen-containing gas is selected to provide a low-k dielectric to photoresist etching selectivity ratio greater than about 5:1 and a low-k dielectric etch rate higher than about 4000 Å/min.

Abstract: An integrated in situ etch process performed in a multichamber substrate processing system having first and second etching chambers. In one embodiment the first chamber includes an interior surface that has been roughened to at least 100 Ra and the second chamber includes an interior surface that has a roughness of less than about 32 Ra. The process includes transferring a substrate having formed thereon in a downward direction a patterned photoresist mask, a dielectric layer, a barrier layer and a feature in the substrate to be contacted into the first chamber where the dielectric layer is etched in a process that encourages polymer formation over the roughened interior surface of the chamber. The substrate is then transferred from the first chamber to the second chamber under vacuum conditions and, in the second chamber, is exposed to a reactive plasma such as oxygen to strip away the photoresist mask deposited over the substrate.

Abstract: We have discovered a method for plasma etching a carbon-containing silicon oxide film which provides excellent etch profile control, a rapid etch rate of the carbon-containing silicon oxide film, and high selectivity for etching the carbon-containing silicon oxide film preferentially to an overlying photoresist masking material. When the method of the invention is used, a higher carbon content in the carbon-containing silicon oxide film results in a faster etch rate, at least up to a carbon content of 20 atomic percent. In particular, the carbon-containing silicon oxide film is plasma etched using a plasma generated from a source gas comprising NH3 and CxFy. It is necessary to achieve the proper balance between the relative amounts of NH3 and CxFy in the plasma source gas in order to provide a balance between etch by-product polymer deposition and removal on various surfaces of the substrate being etched.

Abstract: A method is provided for etching a dielectric structure. The dielectric structure comprises: (a) a layer of undoped silicon oxide or F-doped silicon oxide; and (b) a layer of C,H-doped silicon oxide. The dielectric structure is etched in a plasma-etching step, which plasma-etching step is conducted using a plasma source gas that comprises nitrogen atoms and fluorine atoms. As one example, the plasma source gas can comprise a gaseous species that comprises one or more nitrogen atoms and one or more fluorine atoms (e.g., NF3). As another example, the plasma source gas can comprise (a) a gaseous species that comprises one or more nitrogen atoms (e.g., N2) and (b) a gaseous species that comprises one or more fluorine atoms (e.g., a fluorocarbon gas such as CF4). In this etching step, the layer of C,H-doped silicon oxide is preferentially etched relative to the layer of undoped silicon oxide or F-doped silicon oxide. The method of the present invention is applicable, for example, to dual damascene structures.

Abstract: A substrate is etched in a process zone by placing the substrate in the process zone, providing an energized process gas in the process zone, and exhausting the process gas. A first stage of the etching process is monitored to determine completion of the first stage by detecting the intensities of one or more wavelengths of a radiation emission generated by the energized gas, generating a first signal in relation to the detected intensities, and evaluating the first signal. A second stage of the etching process is monitored to determine completion of the second stage by detecting the intensities of one or more wavelengths of a polarized radiation reflected from the substrate being etched, generating a second signal in relation to the detected intensities, and evaluating the second signal.

Abstract: The present invention provides a novel etching technique for etching a layer of C-doped silicon oxide, such as a partially oxidized organo silane material. This technique, employing CH2F2/Ar chemistry at low bias and low to intermediate pressure, provides high etch selectivity to silicon oxide and improved selectivity to organic photoresist. Structures including a layer of partially oxidized organo silane material (1004) deposited on a layer of silicon oxide (1002) were etched according to the novel technique, forming relatively narrow trenches (1010, 1012, 1014, 1016, 1030, 1032, 1034 and 1036) and wider trenches (1020, 1022, 1040 and 1042). The technique is also suitable for forming dual damascene structures (1152, 1154 and 1156). In additional embodiments, manufacturing systems (1410) are provided for fabricating IC structures of the present invention. These systems include a controller (1400) that is adapted for interacting with a plurality of fabricating stations (1420, 1422, 1424, 1426 and 1428).

Abstract: Copper can be pattern etched in a manner which provides the desired feature dimension and integrity, at acceptable rates, and with selectivity over adjacent materials. To provide for feature integrity, the portion of the copper feature surface which has been etched to the desired dimensions and shape must be protected during the etching of adjacent feature surfaces. This is particularly important for feature sizes less than about 0.5 &mgr;m, where presence of even a limited amount of a corrosive agent can eat away a large portion of the feature.

Abstract: In general, the present disclosure pertains to a method for removing photoresist from locations on a semiconductor structure where its presence is undesired. In one embodiment, a method is disclosed for descumming residual photoresist material from areas where it is not desired after patterning of the photoresist. In another embodiment, a misaligned patterned photoresist is stripped from a semiconductor substrate surface. In particular, the method comprises exposing the semiconductor structure to a plasma generated from a source gas comprising NH3. A substrate bias voltage is utilized in both methods in order to produce anisotropic etching. In the descumming embodiment, the critical dimensions of the patterned photoresist are maintained. In the photoresist stripping embodiment, a patterned photoresist is removed without adversely affecting a partially exposed underlying layer of an organic dielectric.

Abstract: A substrate is etched in a process zone by placing the substrate in the process zone, providing an energized process gas in the process zone, and exhausting the process gas. A first stage of the etching process is monitored to determine completion of the first stage by detecting the intensities of one or more wavelengths of a radiation emission generated by the energized gas, generating a first signal in relation to the detected intensities, and evaluating the first signal. A second stage of the etching process is monitored to determine completion of the second stage by detecting the intensities of one or more wavelengths of a polarized radiation reflected from the substrate being etched, generating a second signal in relation to the detected intensities, and evaluating the second signal.

Abstract: Copper can be pattern etched in a manner which provides the desired feature dimension and integrity, at acceptable rates, and with selectivity over adjacent materials. To provide for feature integrity, the portion of the copper feature surface which has been etched to the desired dimensions and shape must be protected during the etching of adjacent feature surfaces. This is particularly important for feature sizes less than about 0.5 &mgr;m, where presence of even a limited amount of a corrosive agent can eat away a large portion of the feature.

Abstract: A first embodiment of the present invention pertains to a method of patterning a semiconductor device conductive feature while permitting easy removal of any residual masking layer which remains after completion of the etching process. A multi-layered masking structure is used which includes a layer of high-temperature organic-based masking material overlaid by either a patterned layer of inorganic masking material or by a layer of patterned high-temperature imageable organic masking material. The inorganic masking material is used to transfer a pattern to the high-temperature organic-based masking material and is then removed. The high-temperature organic-based masking material is used to transfer the pattern and then may be removed if desired. This method is also useful in the pattern etching of aluminum, even though aluminum can be etched at lower temperatures.

Abstract: Disclosed herein is a post-etch treatment for plasma etched metal-comprising features in semiconductor devices. The post-etch treatment significantly reduces or eliminates surface corrosion of the etched metal-comprising feature. It is particularly important to prevent the formation of moisture on the surface of the feature surface prior to an affirmative treatment to remove corrosion-causing contaminants from the feature surface. Avoidance of moisture formation is assisted by use of a high vacuum; use of an inert, moisture-free purge gas; and by maintaining the substrate at a sufficiently high temperature to volatilize moisture.

Abstract: The present disclosure pertains to a method of patterning a semiconductor device feature which provides for the easy removal of any residual masking layer which remains after completion of a pattern etching process. The method provides for a multi-layered masking structure which includes a layer of high-temperature organic-based masking material overlaid by either a layer of a high-temperature inorganic masking material which can be patterned to provide an inorganic hard mask, or by a layer of high-temperature imageable organic masking material which can be patterned to provide an organic hard mask. The hard masking material is used to transfer a pattern to the high-temperature organic-based masking material, and then the hard masking material is removed. The high-temperature organic-based masking material is used to transfer the pattern to an underlying semiconductor device feature.

Abstract: A first embodiment of the present invention pertains to a method of patterning a semiconductor device conductive feature while permitting easy removal of any residual masking layer which remains after completion of the etching process. A multi-layered masking structure is used which includes a layer of high-temperature organic-based masking material overlaid by either a patterned layer of inorganic masking material or by a layer of patterned high-temperature imageable organic masking material. The inorganic masking material is used to transfer a pattern to the high-temperature organic-based masking material and is then removed. The high-temperature organic-based masking material is used to transfer the pattern and then may be removed if desired. This method is also useful in the pattern etching of aluminum, even though aluminum can be etched at lower temperatures.