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: 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: The present invention provides a method and an apparatus for cleaning substrates. The cleaning chamber defines a processing cavity adapted to accommodate a substrate therein. In one embodiment, the cleaning chamber includes a chamber body having a processing cavity defined therein. A substrate is disposed in the processing cavity without contacting other chamber components by a Bernoulli effect and/or by a fluid cushion above and/or below the substrate. Fluid is flowed into the processing cavity at an angle relative to a radial line of the substrate to induce and/or control rotation of the substrate during a cleaning and drying process.

Abstract: A plasma reactor embodying the invention includes a wafer support and a chamber enclosure member having an interior surface generally facing the wafer support. At least one miniature gas distribution plate for introducing a process gas into the reactor is supported on the chamber enclosure member and has an outlet surface which is a fraction of the area of the interior surface of said wafer support. A coolant system maintains the chamber enclosure member at a low temperature, and the miniature gas distribution plate is at least partially thermally insulated from the chamber enclosure member so that it is maintained at a higher temperature by plasma heating.

Abstract: Apparatus and methods provide a module defining processing regions in which substrates can be processed. One embodiment of the module has a serial arrangement of processing regions, where a first processing region is disposed at a front end portion of the module and a second processing region is defined at a back end portion of the module. A substrate transfer passageway fluidly communicates the first and second processing regions.

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: The present invention provides a method and an apparatus for cleaning substrates. The cleaning chamber defines a processing cavity adapted to accommodate a substrate therein. In one embodiment, the cleaning chamber includes an upper plate, a lower plate and a gas manifold disposed there between. A substrate is disposed in the processing cavity without contacting other chamber components by a Bernoulli effect and/or by a fluid cushion above and/or below the substrate. Fluid is flowed into the processing cavity at an angle relative to a radial line of the substrate to induce rotation of the substrate during a cleaning and drying process. A cleaning process involves flowing one or more fluids onto a surface of the substrate during its rotation. One-sided and two-sided cleaning and drying is provided.

Abstract: The invention solves the problem of continuously monitoring wafer temperature during processing using an optical or fluoro-optical temperature sensor including an optical fiber having an end next to and facing the backside of the wafer. This optical fiber is accommodated without disturbing plasma processing by providing in one of the wafer lift pins an axial void through which the optical fiber passes. The end of the fiber facing the wafer backside is coincident with the end of the hollow lift pin. The other end is coupled via an “external” optical fiber to temperature probe electronics external of the reactor chamber. The invention uses direct wafer temperature measurements with a test wafer to establish a data base of wafer temperature behavior as a function of coolant pressure and a data base of wafer temperature behavior as a function of wafer support or “puck” temperature.

Abstract: An electrostatic or mechanical chuck assembly includes gas inlets only in an annulus-shaped peripheral portion and not in the central region of the chuck. The gas inlets are in fluid communication with one or more gas conduits and supply of the backside of a workpiece, such as a semiconductor wafer, with inert coolant gas or gases. The gas or gases supplied only to the peripheral region of the chuck effectively cool the central region of the chuck by at least two physical mechanisms, including the thermal conduction through the workpiece and diffusion of the gas or gases in the interstitial space(s) between the somewhat irregular facing surfaces of the chuck and of the backside of the workpiece.

Abstract: The invention solves the problem of continuously monitoring wafer temperature during processing using an optical or fluoro-optical temperature sensor including an optical fiber having an end next to and facing the backside of the wafer. This optical fiber is accommodated without disturbing plasma processing by providing in one of the wafer lift pins an axial void through which the optical fiber passes. The end of the fiber facing the wafer backside is coincident with the end of the hollow lift pin. The other end is coupled via an “external” optical fiber to temperature probe electronics external of the reactor chamber. The invention uses direct wafer temperature measurements with a test wafer to establish a data base of wafer temperature behavior as a function of coolant pressure and a data base of wafer temperature behavior as a function of wafer support or “puck” temperature.

Abstract: A chuck 28 for holding a substrate 4 comprises a surface 27 capable of receiving the substrate 4, the surface 27 having a gas inlet port 40 and a gas exhaust port 42. A non-sealing protrusion is between the gas inlet port 40 and the gas exhaust port 42. The non-sealing protrusion 44 impedes the flow of heat transfer gas between the gas inlet port 40 and the gas exhaust port 42 without blocking the flow of heat transfer gas. Preferably, a sealing protrusion 46 is provided around the periphery of the chuck 28 to form a substantially gas-tight seal with the substrate 4 to enclose and prevent leakage of heat transfer gas into a surrounding chamber 6.

Abstract: The invention concerns a plasma reactor employing a chamber enclosure including a process gas inlet and defining a plasma processing region. A workpiece support pedestal capable of supporting a workpiece at processing location faces the plasma processing region, the pedestal and enclosure being spaced from one another to define a pumping annulus therebetween having facing walls in order to permit the process of gas to be evacuated therethrough from the process region. A pair of opposing plasma confinement magnetic poles within one of the facing walls of the annulus, the opposing magnetic poles being axially displaced from one another. The magnetic poles are axially displaced below the processing location by a distance which exceeds a substantial fraction of a spacing between the facing walls of the annulus.

Abstract: The invention is a plasma reactor employing a chamber having a process gas inlet and enclosing a plasma process region. The reactor includes a workpiece support pedestal within the chamber capable of supporting a workpiece at a processing location interfacing with the plasma process region, the support pedestal and the chamber defining an annulus therebetween to permit gas to be evacuated therethrough from the plasma process region. One aspect of the invention includes a ring horseshoe magnet adjacent and about one side of the annulus, the magnet being spaced from the plasma processing location by a spacing substantially greater than the smallest distance across the annulus. The invention further includes the magnet defining opposite poles which are substantially closer together than the spacing of the magnet from the processing location, the magnet being oriented to provide its maximum magnetic flux across the annulus and a minimum of the flux at the plasma processing location.

Abstract: A method and apparatus for retaining a substrate, such as a semiconductor wafer, upon an electrostatic chuck within a semiconductor wafer processing system. Specifically, the apparatus contains high voltage, DC power supply that is capable of both sourcing and sinking current at any polarity of output voltage level. This power supply is coupled to at least one electrode of an electrostatic chuck. Consequently, the power supply can be used to dynamically control the chucking voltage to apply a negative potential difference between said wafer and chuck.

Abstract: A support 55 comprises a dielectric 60 covering a primary electrode 70, the dielectric 60 having a surface 75 adapted to receive a substrate 25 and a conduit 160 that extends through the dielectric 60. The thickness of a portion of the dielectric 60 between an edge 195 of the primary electrode 70 and a surface 180 of the conduit 160 is sufficiently large to reduce the incidence of plasma formation in the conduit 160 when the primary electrode 70 is charged by an RF voltage to form a plasma of gas in the chamber 30 during processing of the substrate 25.

Abstract: A support 55 comprises a dielectric 60 covering a primary electrode 70, the dielectric 60 having a surface 75 adapted to receive a substrate 25 and a conduit 160 that extends through the dielectric 60. The thickness of a portion of the dielectric 60 between an edge 195 of the primary electrode 70 and a surface 180 of the conduit 160 is sufficiently large to reduce the incidence of plasma formation in the conduit 160 when the primary electrode 70 is charged by an RF voltage to form a plasma of gas in the chamber 30 during processing of the substrate 25.

Abstract: A method and apparatus for retaining a substrate, such as a semiconductor wafer, upon an electrostatic chuck within a semiconductor wafer processing system. Specifically, the invention contains high voltage, DC power supply that is capable of both sourcing and sinking current at any polarity of output voltage level. This power supply is coupled to at least one electrode of an electrostatic chuck. Consequently, the power supply can be used to dynamically control the chucking voltage in response to any indicia of optimal chucking including leakage current, wafer-to-chuck potential, backside gas leakage rate, and the like.

Abstract: In a substrate vacuum processing chamber, a second inner slit passage door apparatus and method to supplement the normal slit valve and its door at the outside of the chamber. The inner slit passage door, blocks the slit passage at or adjacent the substrate processing location in a vacuum processing chamber to prevent process byproducts from depositing on the inner surfaces of the slit passage beyond the slit passage door and improves the uniformity of plasma in the processing chamber by eliminating a large cavity adjacent to the substrate processing location into which the plasma would otherwise expand.

Abstract: The invention contours the chamber surface overlying semiconductor wafer being processed (i.e., the chamber ceiling) in such a way as to promote or optimize the diffusion of plasma ions from their regions of origin to other regions which would otherwise have a relative paucity of plasma ions. This is accomplished by providing a greater chamber volume over those areas of the wafer otherwise experiencing a shortage of plasma ions and a smaller chamber volume over those areas of the wafer experiencing a plentitude of plasma ions (e.g, due to localized plasma generation occurring over the latter areas). Thus, the ceiling is contoured to promote a plasma ion diffusion which best compensates for localized or non-uniform patterns in plasma ion generation typical of an inductively coupled source (e.g., an overhead inductive antenna).

Abstract: A DC power supply having a pair of "piggybacked" voltage supplies, where a reference voltage supply provides a reference voltage for a variable voltage supply and each voltage supply is coupled to a current sink. The power supply is capable of sourcing and sinking current through a single output terminal when supplying a positive or negative output voltage with respect to ground.