Abstract: A method of etching a noble metal electrode layer disposed on a substrate to produce a semiconductor device including a plurality of electrodes separated by a distance equal to or less than about 0.35 ?m and having a noble metal profile equal to or greater than about 80°. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the noble metal electrode layer by employing a high density inductively coupled plasma of an etchant gas comprising a gas selected from the group consisting of nitrogen, oxygen, a halogen (e.g., chlorine), argon, and a gas selected from the group consisting of BCl3, HBr, and SiCl4 mixtures thereof. Masking methods and etching sequences for patterning high density RAM capacitors are also provided.

Abstract: A method for preventing electrical short circuits in a multi-layer magnetic film stack comprises providing a film stack that includes a layer of magnetic material having an exposed surface. A protective layer is deposited on the exposed surface of the magnetic layer. The protective layer may comprise, for example, a fluorocarbon or a hydrofluorocarbon. The film stack is etched and the protective layer protects the exposed surface from a conductive residue produced while etching the film stack. The method may be used in film stacks to form a magneto-resistive random access memory (MRAM) device.

Abstract: A method and apparatus for etching a magnetic memory cell stack are described. More particularly, HCl is used as a main etchant gas for etching a magnetic memory cell stack. HCl is used in part to reduce corrosion and improve selectivity. Additionally, use of an amorphous carbon or hydrocarbon based polymer resin for a hard mask is described, as well as a post-etch passivation with a water rinse, a water vapor plasma treatment or an ammonia plasma treatment. Moreover, in an embodiment, a diffusion barrier layer dispose most of the magnetic memory cell stack is etched with hydrogen and fluorine containing gas in a separate process chambers.

Abstract: A method of etching a platinum electrode layer disposed on a substrate to produce a semiconductor device including a plurality of electrodes separated by a distance equal to or less than about 0.3 &mgr;m and having a platinum profile equal to or greater than about 85°. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the platinum electrode layer by employing a high density inductively coupled plasma of an etchant gas comprising chlorine, argon and a gas selected from the group consisting of BCl3, HBr, and mixtures thereof. A semiconductor device having a substrate and a plurality of platinum electrodes supported by the substrate. The platinum electrodes have a dimension (e.g., a width) which include a value equal to or less than about 0.3 &mgr;m and a platinum profile equal to or greater than about 85°.

Abstract: Contaminants are generated during etching processes for forming electrodes of storage capacitors for very high density future memory cells, such as ferroelectric random access memory (FeRAM) cells. These contaminants include significant quantities of noble metals, and in particular iridium and iridium compound particulates. In order to prevent undesirable iridium and iridium compound particulates from adversely affecting subsequent etching processes performed in the chamber, the plasma metal etch chamber is seasoned by exposing interior surfaces of the chamber to a seasoning plasma generated from a gas mixture comprising at least two gases selected from the group consisting of BCl3, HBr, and CF4. The chamber seasoning method of the invention is also applicable to etch processes involving other noble metals, such as platinum.

Abstract: A method of etching a platinum electrode layer disposed on a substrate to produce a semiconductor device including a plurality of platinum electrodes. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the platinum electrode layer by employing a plasma of an etchant gas comprising nitrogen and a halogen (e.g. chlorine), and a gas selected from the group consisting of a noble gas (e.g. argon), BCl3, HBr, SiCl4 and mixtures thereof. The substrate may be heated in a reactor chamber having a dielectric window including a deposit-receiving surface having a surface finish comprising a peak-to-valley roughness height with an average height value of greater than about 1000 Å.

Abstract: A simple method of forming a cup capacitor is disclosed. The method typically involves only “dry” deposition and etching steps, allowing applicants' method to be performed in a single processing apparatus, if so desired.

Abstract: We have discovered a method of reducing the effect of material sputtered/etched during the preheating of a substrate. One embodiment of the method pertains to preheating a substrate which includes a metal-containing layer which is to be pattern etched subsequent to preheating. The method includes exposing the substrate to a preheating plasma which produces a deposit or residue during preheating which is more easily etched than said metal-containing layer during the subsequent plasma etching of said metal-containing layer.

Abstract: A method of processing a substrate 30 comprises exposing the substrate 30 to an energized process gas to etch features 67 on the substrate 30 and exposing the substrate 30 to an energized cleaning gas to remove etchant residue 70 and/or remnant resist 60 from the substrate 30. To enhance the cleaning process, the substrate 30 may be treated before, during or after the cleaning process by exposing the substrate 30 to an energized treating gas comprising a halogen species.

Abstract: We have discovered a method of reducing the effect of material sputtered/etched during the preheating of a substrate. One embodiment of the method pertains to the preheating of a substrate which includes a material which is to be pattern etched at a temperature in excess of 150° C. The method comprises exposing the substrate to a preheating plasma generated from a plasma source gas which includes a reactive gas that aids in the production of a sputtered/etched residue during the preheating which is more easily etched during a subsequent pattern etching step than the material which is being pattern etched. In another embodiment of the method, the reactive gas in the preheating plasma source gas is slightly reactive with the material which is to etched during the subsequent pattern etching step.

Abstract: A method for preventing electrical short circuits in a multi-layer magnetic film stack comprises providing a film stack that includes a layer of magnetic material having an exposed surface. A protective layer is deposited on the exposed surface of the magnetic layer. The protective layer may comprise, for example, a fluorocarbon or a hydrofluorocarbon. The film stack is etched and the protective layer protects the exposed surface from a conductive residue produced while etching the film stack. The method may be used in film stacks to form a magneto-resistive random access memory (MRAM) device.

Abstract: A method and apparatus for etching a magnetic memory cell stack are described. More particularly, HCl is used as a main etchant gas for etching a magnetic memory cell stack. HCl is used in part to reduce corrosion and improve selectivity. Additionally, use of an amorphous carbon or hydrocarbon based polymer resin for a hard mask is described, as well as a post-etch passivation with a water rinse, a water vapor plasma treatment or an ammonia plasma treatment.

Abstract: Disclosed herein is a method of etching platinum using a silicon carbide mask. The method comprises providing an etch stack including a patterned silicon carbide layer overlying a layer of platinum, then pattern etching the platinum layer using a plasma generated from a source gas comprising Cl2, BCl3, and a nonreactive, diluent gas. The silicon carbide mask can be deposited and patterned using standard industry techniques, and can be easily removed without damaging either the platinum or an underlying doped substrate material. The method provides a smooth platinum etch profile and an etch profile angle of about 75° to about 90°. Also disclosed herein are methods of forming semiconductor structures useful in the preparation of DRAM and FeRAM cells.

Abstract: A method of etching a platinum electrode layer disposed on a substrate to produce a semiconductor device including a plurality of electrodes separated by a distance equal to or less than about 0.3 &mgr;m and having a platinum profile equal to or greater than about 85°. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the platinum electrode layer by employing a high density inductively coupled plasma of an etchant gas comprising chlorine, argon and a gas selected from the group consisting of BCl3, HBr, and mixtures thereof. A semiconductor device having a substrate and a plurality of platinum electrodes supported by the substrate. The platinum electrodes have a dimension (e.g., a width) which include a value equal to or less than about 0.3 &mgr;m and a platinum profile equal to or greater than about 85°.

Abstract: A method of etching a metal or metal oxide, including a platinum family metal or a platinum family metal oxide. A wafer is first provided which comprises: (a) a semiconductor substrate, (b) a metal or metal oxide layer over the semiconductor substrate, and (c) a titanium containing patterned mask layer having one or more apertures formed therein positioned over the metal or metal oxide layer. The metal or metal oxide is then etched through the apertures in the mask layer by a plasma etching step that uses plasma source gases comprising the following: (a) a gas that comprises one or more carbon-oxygen bonds (for example, CO gas or CO2 gas) and (b) a gas that comprises one or more chlorine atoms (for example, Cl2 gas, carbon tetrachloride gas, silicon tetrachloride gas or boron trichloride gas).

Abstract: A method of etching a noble metal electrode layer disposed on a substrate to produce a semiconductor device including a plurality of electrodes separated by a distance equal to or less than about 0.35 &mgr;m and having a noble metal profile equal to or greater than about 80°. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the noble metal electrode layer by employing a high density inductively coupled plasma of an etchants gas comprising a gas selected from the group consisting nitrogen, oxygen, a halogen (e.g., chlorine), argon, and a gas selected from the group consisting of BCl3, HBr, and SiCl4 mixtures thereof. A semiconductor device having a substrate and a plurality of noble metal electrodes supported by the substrate. The noble metal electrodes have a dimension (e.g., a width) which include a value equal to or less than about 0.3 &mgr;m and a platinum profile equal to or greater than about 85°.

Abstract: Disclosed herein is a method of etching platinum using a silicon carbide mask. The method comprises providing an etch stack including a patterned silicon carbide layer overlying a layer of platinum, then pattern etching the platinum layer using a plasma generated from a source gas comprising Cl2, BCl3, and a nonreactive, diluent gas. The silicon carbide mask can be deposited and patterned using standard industry techniques, and can be easily removed without damaging either the platinum or an underlying doped substrate material. The method provides a smooth platinum etch profile and an etch profile angle of about 75° to about 90°. Also disclosed herein are methods of forming semiconductor structures useful in the preparation of DRAM and FeRAM cells.

Abstract: A method of etching a metal or metal oxide, including a platinum family metal or a platinum family metal oxide. A wafer is first provided which comprises: (a) a semiconductor substrate, (b) a metal or metal oxide layer over the semiconductor substrate, and (c) a titanium containing patterned mask layer having one or more apertures formed therein positioned over the metal or metal oxide layer. The metal or metal oxide is then etched through the apertures in the mask layer by a plasma etching step that uses plasma source gases comprising the following: (a) a gas that comprises one or more carbon-oxygen bonds (for example, CO gas or CO2 gas) and (b) a gas that comprises one or more chlorine atoms (for example, Cl2 gas, carbon tetrachloride gas, silicon tetrachloride gas or boron trichloride gas).

Abstract: Nonvolatile etch byproduct contaminants are generated during etching processes for forming electrodes of storage capacitors for very high density future memory cells, such as ferroelectric random access memory (FeRAM) cells. These contaminants include significant quantities of metals and metal compounds. In order to prevent undesirable metal etch byproduct particulates from adversely affecting subsequent etching processes performed in the chamber, the plasma metal etch chamber is seasoned by placing a substrate in the chamber, then exposing the substrate and interior surfaces of the chamber to a seasoning plasma generated from a source gas that includes at least one principal etchant gas used during an etch process which produced the nonvolatile etch byproducts. The method is performed at a substrate temperature that is equal to or greater than a substrate temperature at which the nonvolatile etch byproducts were produced.

Abstract: A simple method of forming a cup capacitor is disclosed. The method typically involves only “dry” deposition and etching steps, allowing applicants' method to be performed in a single processing apparatus, if so desired.