Abstract: Apparatus for plasma etching a layer of material upon a substrate comprising an anode having a first region protruding from a second region, wherein the second region defines a plane and the first region extends from said plane. In one embodiment, at least one solenoid is disposed near the apparatus to magnetize the plasma.

Abstract: Disclosed herein is a method of etching a trench in a silicon-containing dielectric material, in the absence of a trench etch-stop layer, where the silicon-containing dielectric material has a dielectric constant of about 4 or less. The method comprises exposing the dielectric material to a plasma generated from a source gas comprising a fluorine-containing etchant gas and an additive gas selected from the group consisting of carbon monoxide (CO), argon, and combinations thereof. A volumetric flow ratio of the additive gas to the fluorine-containing etchant gas is within the range of about 1.25:1 to about 20:1 (more typically, about 2.5:1 to about 20:1), depending on the particular fluorine-containing etchant gas used. The method provides good control over critical dimensions and etch profile during trench etching. Also disclosed herein is a method of forming a dual damascene structure, without the need for an intermediate etch stop layer.

Abstract: A plasma processing chamber and method provides the ability to make dissociation of reactive gasses independent from ionization of dilutant gasses. It also provides the ability to control the amount of dissociation of reactive gasses. The distance between the injection points for the reactive gasses and the dilutant gasses is substantially larger than the distance between the wafer pedestal and where the reactive gasses are injected. This distance between injection locations helps makes dissociation of reactive gasses independent from ionization of dilutant gasses. The use of a secondary excitation source that excites substantially only the dilutant gasses further contributes to the ability to control dissociation of reactive gasses independently of ionization of dilutant gasses. The ability to adjust the location of the injection point of the reactive gasses further provides the ability to control dissociation in a novel way.

Abstract: A method is described for decreasing the critical dimensions of integrated circuit features in which a first masking layer (101) is deposited, patterned and opened in the manner of typical feature etching, and a second masking layer (201) is deposited thereon prior to etching the underlying insulator. The second masking layer is advantageously coated in a substantially conformal manner. Opening the second masking layer while leaving material of the second layer on the sidewalls of the first masking layer as spacers leads to reduction of the feature critical dimension in the underlying insulator. Ashable masking materials, including amorphous carbon and organic materials are removable without CMP, thereby reducing costs. Favorable results are also obtained utilizing more than one masking layer (101, 301) underlying the topmost masking layer (302) from which the spacers are formed. Embodiments are also described in which slope etching replaces the addition of a separate spacer layer.

Abstract: Disclosed herein is a method of etching a trench in a silicon-containing dielectric material, in the absence of a trench etch-stop layer, where the silicon-containing dielectric material has a dielectric constant of about 4 or less. The method comprises exposing the dielectric material to a plasma generated from a source gas comprising a fluorine-containing etchant gas and an additive gas selected from the group consisting of carbon monoxide (CO), argon, and combinations thereof. A volumetric flow ratio of the additive gas to the fluorine-containing etchant gas is within the range of about 1.25:1 to about 20:1 (more typically, about 2.5:1 to about 20:1), depending on the particular fluorine-containing etchant gas used. The method provides good control over critical dimensions and etch profile during trench etching. Also disclosed herein is a method of forming a dual damascene structure, without the need for an intermediate etch stop layer.

Abstract: An oxide etch process practiced in a plasma etch reactor, such as a magnetically enhanced reactive ion etch (MERIE) reactor. The etching gas includes approximately equal amounts of a hydrogen-free fluorocarbon, most preferably C4F6, and oxygen and a much larger amount of argon diluent gas. The magnetic field is preferably maintained above about 50 gauss and the pressure at 40 milliTorr or above with chamber residence times of less than 70 milliseconds. A two-step process may be used for etching holes with very high aspect ratios. In the second step, the magnetic filed and the oxygen flow are reduced. Other fluorocarbons may be substituted which have F/C ratios of less than 2 and more preferably no more than 1.6 or 1.5.

Abstract: An oxide etching process, particularly useful for selectively etching oxide over a feature having a non-oxide composition, such as silicon nitride and especially when that feature has a corner that is prone to faceting during the oxide etch. One aspect of the invention uses one of four hydrogen-free fluorocarbons having a low F/C ratio, specifically hexafluorobutadiene (C4F6), octafluoropentadiene (C5F8), hexafluorocyclobutene (C4F6), and hexafluorobenzene (C6F6). At least hexafluorobutadiene has a boiling point below 10° C. and is commercially available. Another aspect of the invention, uses an unsaturated fluorocarbon such as pentafluoropropylene (C3HF5), and trifluoropropyne (C3HF3), both of which have boiling points below 10° C. and are commercially available.

Abstract: A substrate processing chamber has a substrate support to support a substrate in the housing. A shockwave gas energizer is provided to generate shockwaves to at least partially energize a process gas and provide the energized process gas into the housing. In one version, the shockwave gas energizer comprises a gas nozzle adapted to accelerate the process gas and a gas flow blocker to obstruct the accelerated flow of the process gas emanating from the gas nozzle to generate the shockwaves. The chamber also has an exhaust to exhaust the process gas from the housing.

Abstract: A capacitively coupled reactor for plasma etch processing of substrates at subatmospheric pressures includes a chamber body defining a processing volume, a lid provided upon the chamber body, the lid being a first electrode, a substrate support provided in the processing volume and comprising a second electrode, a radio frequency source coupled at least to one of the first and second electrodes, a process gas inlet configured to deliver process gas into the processing volume, and an evacuation pump system having pumping capacity of at least 1600 liters/minute. The greater pumping capacity controls residency time of the process gases so as to regulate the degree of dissociation into more reactive species.

Abstract: Within both a magnetically enhanced plasma apparatus and a magnetically enhanced plasma method there is employed: (1) a repetitive and geometrically selective pulsing of a magnetic field from a first level to a second level within a reactor chamber; and (2) a repetitive pulsing of a radio frequency power from a first level to a second level within the reactor chamber when repetitively and geometrically selectively pulsing from the first level to the second level the magnetic field within the reactor chamber. The concurrent repetitive pulsings provide a plasma within the reactor chamber with enhanced plasma uniformity and enhanced ion energy control.

Abstract: An oxide etching process, particularly useful for selectively etching oxide over a feature having a non-oxide composition, such as silicon nitride and especially when that feature has a corner that is prone to faceting during the oxide etch. The invention uses a heavy perfluorocarbon, for example, hexafluorobutadiene (C4F6) or hexafluorobenzene (C6F6). The fluorocarbon together with a substantial amount of a noble gas such as argon is excited into a high-density plasma in a reactor which inductively couples plasma source power into the chamber and RF biases the pedestal electrode supporting the wafer. A more strongly polymerizing fluorocarbon such as difluoromethane (CH2F2) is added in the over etch to protect the nitride corner. Oxygen or nitrogen may be added to counteract the polymerization. The same chemistry can be used in a magnetically enhanced reactive ion etcher (MERIE) or with a remote plasma source.

Abstract: A plasma etching process, particularly useful for selectively etching oxide over a feature having a non-oxide composition, such as silicon nitride and especially when that feature has a comer that is prone to faceting during the oxide etch. A primary fluorine- containing gas, preferably hexafluorobutadiene (C4F6), is combined with a significantly larger amount of the diluent gas xenon (Xe) enhance nitride selectivity without the occurrence of etch stop. The chemistry is also useful for etching oxides in which holes and comers have already been formed, for which the use of xenon also reduces faceting of the oxide. For this use, the relative amount of xenon need not be so high. The invention may be used with related heavy fluorocarbons and other fluorine-based etching gases.

Abstract: An oxide etch process practiced in a plasma etch reactor, such as a magnetically enhanced reactive ion etch (MERIE) reactor. The etching gas includes approximately equal amounts of a hydrogen-free fluorocarbon, most preferably C4F6, and oxygen and a much larger amount of argon diluent gas. The magnetic field is preferably maintained above about 50 gauss and the pressure at 40 milliTorr or above with chamber residence times of less than 70 milliseconds. A two-step process may be used for etching holes with very high aspect ratios. In the second step, the magnetic filed and the oxygen flow are reduced. Other fluorocarbons may be substituted which have F/C ratios of less than 2 and more preferably no more than 1.6 or 1.5.

Abstract: An oxide etch process practiced in magnetically enhanced reactive ion etch (MERIE) plasma reactor. The etching gas includes approximately equal amounts of a hydrogen-free fluorocarbon, most preferably C4F6, and oxygen and a much larger amount of argon diluent gas. The magnetic field is preferably maintained above about 50 gauss and the pressure at 40 milliTorr or above with chamber residence times of less than 70 milliseconds. A two-step process may be used for etching holes with very high aspect ratios. In the second step, the magnetic filed and the oxygen flow are reduced. Other fluorocarbons may be substituted which have F/C ratios of less than 2 and more preferably no more than 1.6 or 1.5.

Abstract: A substrate cleaning method comprises exposing a substrate 30 to an energized process gas to remove residue 60 and resist material 50 from the substrate 30. In one version, the process gas comprises cleaning gas, such as an oxygen-containing gas, and an additive gas, such as NH3. In one version, the process gas is introduced to remove residue 60 and resist material 50 from the substrate and to remove residue from surfaces in the process chamber 75.

Abstract: A plasma reactor for processing a semiconductor workpiece, includes a vacuum chamber including a side wall and an overhead ceiling, a wafer support pedestal within the vacuum chamber, gas injection passages to the interior of the vacuum chamber coupled to a process gas supply, and a first RF power source for applying RF power to the wafer support pedestal for generating a capacitively coupled plasma. It further includes plural electromagnets near said chamber, and a time-varying current source connected to said plural electromagnets for producing a magnet field that rotates relative to said wafer pedestal. An inductive plasma source power applicator is provided near said chamber and a second RF power source is provided for applying RF power to said inductive plasma source power applicator for generating an inductively coupled plasma within said chamber.

Abstract: A method of depositing and etching dielectric layers having low dielectric constants and etch rates that vary by at least 3:1 for formation of horizontal interconnects. The amount of carbon or hydrogen in the dielectric layer is varied by changes in deposition conditions to provide low k dielectric layers that can replace etch stop layers or conventional dielectric layers in damascene applications. A dual damascene structure having two or more dielectric layers with dielectric constants lower than about 4 can be deposited in a single reactor and then etched to form vertical and horizontal interconnects by varying the concentration of a carbon:oxygen gas such as carbon monoxide. The etch gases for forming vertical interconnects preferably comprises CO and a fluorocarbon, and CO is preferably excluded from etch gases for forming horizontal interconnects.

Abstract: A method of depositing and etching dielectric layers having low dielectric constants and etch rates that vary by at least 3:1 for formation of horizontal interconnects. The amount of carbon or hydrogen in the dielectric layer is varied by changes in deposition conditions to provide low k dielectric layers that can replace etch stop layers or conventional dielectric layers in damascene applications. A dual damascene structure having two or more dielectric layers with dielectric constants lower than about 4 can be deposited in a single reactor and then etched to form vertical and horizontal interconnects by varying the concentration of a carbon:oxygen gas such as carbon monoxide. The etch gases for forming vertical interconnects preferably comprises CO and a fluorocarbon, and CO is preferably excluded from etch gases for forming horizontal interconnects.

Abstract: A thermally controlled chamber liner comprising a passage having an inlet and outlet adapted to flow a fluid through the one or more fluid passages formed at least partially therein. The chamber liner may comprise a first liner, a second liner or both a first liner and a second liner. The thermally controlled chamber liner maintains a predetermined temperature by running fluid from a temperature controlled, fluid source through the fluid passages. By maintaining a predetermined temperature, deposition of films on the chamber liner is discouraged and particulate generation due to stress cracking of deposited films is minimized.

Abstract: An oxide etching process, particularly useful for selectively etching oxide over a feature having a non-oxide composition, such as silicon nitride and especially when that feature has a corner that is prone to faceting during the oxide etch. The invention uses one of three hydrogen-free fluorocarbons having a low F/C ratio, specifically hexafluorobutadiene (C4F6), hexafluorocyclobutene (C4F6), and hexafluorobenzene (C6F6). At least hexafluorobutadiene has a boiling point below 10° C. and is commercially available. The fluorocarbon together with a substantial amount of a noble gas such as argon is excited into a high-density plasma in a reactor which inductively couples plasma source power into the chamber and RF biases the pedestal electrode supporting the wafer. Preferably, one of two two-step etch process is used. In the first, the source and bias power are reduced towards the end of the etch.