Abstract: A system is disclosed for speeding workpiece thoughput in low pressure, high temperature semiconductor processing reactor. The system includes apparatus for loading a workpiece into a chamber at atmospheric pressure, bringing the chamber down to an intermediate pressure, and heating the wafer while under the intermediate pressure. The chamber is then pumped down to the operating pressure. The preferred embodiments involve single wafer plasma ashers, where a wafer is loaded onto lift pins at a position above a wafer chuck, the pressure is rapidly pumped down to about 40 Torr by rapidly opening and closing an isolation valve, and the wafer is simultaneously lowered to the heated chuck. Alternatively, the wafer can be pre-processed to remove an implanted photoresist crust at a first temperature and the chamber then backfilled to about 40 Torr for further heating to close to the chuck temperature.

Abstract: Methods and structures are provided for extremely flat wafer chucks, allowing close thermal contact uniformly across a semiconductor processing substrate. An upper and a lower section are tightly fit to one another with flat inner surfaces in face-to-face contact. The sections also define at least one groove therebetween. The two sections have asymmetrical thickness, but the groove defined therebetween is correspondingly asymmetrical such that the groove is centered in the assembled chuck. A heater element, such as a resistive heater, is placed within the groove with some clearance prior to assembling the upper and lower sections. After assembly and tightening, the chuck is thermally cycled above the normal operating temperature prior to secondary machining, thus assuring flatness that is maintained during high temperature operation.

Abstract: A method is disclosed for speeding workpiece thoughput in low pressure, high temperature semiconductor processing reactor. The method includes loading a workpiece into a chamber at atmospheric pressure, bringing the chamber down to an intermediate pressure, and heating the wafer while under the intermediate pressure. The chamber is then pumped down to the operating pressure. The preferred embodiments involve single wafer plasma ashers, where a wafer is loaded onto lift pins at a position above a wafer chuck, the pressure is rapidly pumped down to about 40 Torr by rapidly opening and closing an isolation valve, and the wafer is simultaneously lowered to the heated chuck. Alternatively, the wafer can be pre-processed to remove an implanted photoresist crust at a first temperature and the chamber then backfilled to about 40 Torr for further heating to close to the chuck temperature. At 40 Torr, the heat transfer from the chuck to the wafer is relatively fast, but still slow enough to avoid thermal shock.

Abstract: An end-effector with integrated cooling features comprises heat transferring mechanisms that transfer heat energy away from the end-effector. The end-effector advantageously minimizes the cooling overhead of a processed substrate as it is transported from a process module to a low-cost storage cassette. The reduced cooling overhead of the processed substrate, as a consequence, improves substrate throughput. In the preferred embodiments, the heat transferring mechanisms include a high surface area heat sink connecting the substrate-supporting paddle with a robot arm. Cooling fins can enhance surface area and thus enhance heat dissipation from the heat sink. Cooling channels can extend through paddle and heat sink, either containing circulating fluid for carrying heat beyond the end-effector or a phase changing material in an enclosed heat pipe.

Abstract: A workpiece support or chuck that rapidly heats and cools a semiconductor workpiece is disclosed. A heat source and a cooling source, maintained at different temperatures, alternately communicate with the chuck. In one embodiment, the heat source and cooling source alternately provide relatively “hot” and “cold” heat transfer fluids to fluid channels within the workpiece chuck. Accordingly, a semiconductor workpiece in contact with the chuck rapidly heats to the temperature of the hot fluid, or rapidly cools to the temperature of the cold fluid, depending upon which fluid flowing through the chuck. In another embodiment, the heat source comprises a movable resistive heating block at a first temperature that is placed in contact with the chuck during heating, and is removed from the chuck while colder heat transfer fluid circulates within the chuck. Optionally, inert fluid can be provided to purge heat transfer fluid from the chuck channels between heating and cooling steps.

Abstract: A remote plasma generator, coupling microwave frequency energy to a gas and delivering radicals to a downstream process chamber, includes several features which, in conjunction, enable highly efficient radical generation. In the illustrated embodiments, more efficient delivery of oxygen and fluorine radicals translates to more rapid photoresist etch or ash rates. A single-crystal, one-piece sapphire applicator and transport tube minimizes recombination of radicals in route to the process chamber and includes a bend to avoid direct line of sight from the glow discharge to the downstream process chamber. Microwave transparent cooling fluid within a cooling jacket around the applicator enables high power, high temperature plasma production. Additionally, dynamic impedance matching via a sliding short at the terminus of the microwave cavity reduces power loss through reflected energy. At the same time, a low profile microwave trap produces a more dense plasma to increase radical production.

Abstract: A method is disclosed for speeding workpiece thoughput in low pressure, high temperature semiconductor processing reactor. The method includes loading a workpiece into a chamber at atmospheric pressure, bringing the chamber down to an intermediate pressure, and heating the wafer while under the intermediate pressure. The chamber is then pumped down to the operating pressure. The preferred embodiments involve single wafer plasma ashers, where a wafer is loaded onto lift pins at a position above a wafer chuck, the pressure is rapidly pumped down to about 40 Torr by rapidly opening and closing an isolation valve, and the wafer is simultaneously lowered to the heated chuck. Alternatively, the wafer can be pre-processed to remove an implanted photoresist crust at a first temperature and the chamber then backfilled to about 40 Torr for further heating to close to the chuck temperature. At 40 Torr, the heat transfer from the chuck to the wafer is relatively fast, but still slow enough to avoid thermal shock.

Abstract: The present invention concerns a method for stripping the photoresist layer and the crust from a semiconductor. The crust has been formed with as a result of an ion implantation step, wherein the method comprises an ion assisted plasma step using a mixture of water vapour, helium and a F-containing compound in which radicals are generated, and the step of contacting said photoresist layer and crust with said radicals to remove said photoresist layer and crust from said semiconductor surface. Said plasma step is preferably an ion assisted plasma step.

Abstract: A remote plasma generator, coupling microwave frequency energy to a gas and delivering radicals to a downstream process chamber, includes several features which, in conjunction, enable highly efficient radical generation. In the illustrated embodiments, more efficient delivery of oxygen and fluorine radicals translates to more rapid photoresist etch or ash rates. A single-crystal, one-piece sapphire applicator and transport tube minimizes recombination of radicals in route to the process chamber and includes a bend to avoid direct line of sight from the glow discharge to the downstream process chamber. Microwave transparent cooling fluid within a cooling jacket around the applicator enables high power, high temperature plasma production. Additionally, dynamic impedance matching via a sliding short at the terminus of the microwave cavity reduces power loss through reflected energy. At the same time, a low profile microwave trap produces a more dense plasma to increase radical production.

Abstract: A remote plasma generator, coupling microwave frequency energy to a gas and delivering radicals to a downstream process chamber, includes several features which, in conjunction, enable highly efficient radical generation. In the illustrated embodiments, more efficient delivery of oxygen and fluorine radicals translates to more rapid photoresist etch or ash rates. A single-crystal, one-piece sapphire applicator and transport tube minimizes recombination of radicals in route to the process chamber and includes a bend to avoid direct line of sight from the glow discharge to the downstream process chamber. Microwave transparent cooling fluid within a cooling jacket around the applicator enables high power, high temperature plasma production. Additionally, dynamic impedance matching via a sliding short at the terminus of the microwave cavity reduces power loss through reflected energy. At the same time, a low profile microwave trap produces a more dense plasma to increase radical production.

Abstract: Workpieces, such as, semiconductor wafers, are continuously manufactured by repetitively alternately switching a common radio frequency power source between a plurality of downstream or in-chamber processing reactors and actively processing one workpiece in a vacuum in an operating one of the processing chambers while simultaneously executing with a robot at atmospheric pressure the overhead tasks relative to next processing another workpiece in the other processing chamber. The active processing of the workpieces in alternate chambers does not overlap, and the robot starts and completes all of its preparatory tasks during the active processing step during the time when a chamber's door is closed thereby providing virtual zero overhead. System architecture allows eliminating all redundant components other than the dual chambers which operate in parallel. For a modest cost increase for the second chamber throughput is trebled and overall costs significantly reduced.

Abstract: A parallel plate reactor having a grounded grid disposed between an RF powered electrode and a grounded electrode upon which a substrate is disposed. A method of utilizing the above apparatus consists of etching the substrate using a composition of 30-100% NF.sub.3 (nitrogen trifluoride) at 25 SCCM (standard cubic centimeter per minute) and 0-70% He (helium) at 75 SCCM to etch a layer of PECVD (plasma enhanced chemical vapor deposition) Si.sub.3 N.sub.4 (silicon nitride). The etching takes place at 200 mtorr to 5 torr pressure and 50-400 watts RF power.

Abstract: A parallel plate reactor having a grounded grid disposed between an RF powered electrode and a grounded electrode upon which a substrate is disposed. A method of utilizing the above apparatus consists of etching the substrate using a composition of 30-100% NF.sub.3 (nitrogen trifluoride) at 25 SCCM (standard cubic centimeter per minute) and 0-70% He (helium) at 75 SCCM to etch a layer of PECVD (plasma enchanced chemcial vapor deposition) Si.sub.3 N.sub.4 (silicon nitride). The etching takes place at 200 mtorr to 5 torr pressure and 50-400 watts RF power.

Abstract: A parallel plate plasma type etching apparatus is provided with a temperature control chuck 44 so that elevated substrate temperatures are controlled. With an elevated substrate temperature, the reaction rate is increased. With positive temperature control, the likelihood of damage to the semiconductor devices is significantly reduced. The chuck is provided with a large number of equally spaced electrical heaters 72 and control of the heaters is by a temperature sensor 74.