Patent application number | Description | Published |
20130284604 | METHOD AND APPARATUS FOR ELECTROPLATING SEMICONDUCTOR WAFER WHEN CONTROLLING CATIONS IN ELECTROLYTE - Apparatus and methods for electroplating metal onto substrates are disclosed. The electroplating apparatus comprise an electroplating cell and at least one oxidization device. The electroplating cell comprises a cathode chamber and an anode chamber separated by a porous barrier that allows metal cations to pass through but prevents organic particles from crossing. The oxidation device (ODD) is configured to oxidize cations of the metal to be electroplated onto the substrate, which cations are present in the anolyte during electroplating. In some embodiments, the ODD is implemented as a carbon anode that removes Cu(I) from the anolyte electrochemically. In other embodiments, the ODD is implemented as an oxygenation device (OGD) or an impressed current cathodic protection anode (ICCP anode), both of which increase oxygen concentration in anolyte solutions. Methods for efficient electroplating are also disclosed. | 10-31-2013 |
20130323930 | Selective Capping of Metal Interconnect Lines during Air Gap Formation - Provided are methods and systems for forming air gaps in an interconnect layer between adjacent conductive lines. Protective layers may be selectively formed on exposed surfaces of the conductive lines, while structures in between the lines may remain unprotected. These structures may be made from a sacrificial material that is later removed to form voids. In certain embodiments, the structures are covered with a permeable non-protective layer that allows etchants and etching products to pass through during removal. When a work piece having a selectively formed protective layer is exposed to gas or liquid etchants, these etchants remove the sacrificial material without etching or otherwise impacting the metal lines. Voids formed in between these lines may be then partially filled with a dielectric material to seal the voids and/or protect sides of the metal lines. Additional interconnect layers may be formed above the processed layer containing air gaps. | 12-05-2013 |
20140199497 | METHODS FOR REDUCING METAL OXIDE SURFACES TO MODIFIED METAL SURFACES - Method and apparatus for reducing metal oxide surfaces to modified metal surfaces are disclosed. Metal oxide surfaces are reduced to form a film integrated with a metal seed layer by contacting a solution with a reducing agent with the metal oxide surfaces. The solution with the reducing agent can contact the metal oxide surfaces under conditions that form an integrated film with the metal seed layer, and that reduces reoxidation from exposure the ambient environment. In some embodiments, an additive can be included with the reducing agent to form a surface protecting layer on the metal seed layer. In some embodiments, the metal is copper used in damascene copper structures. | 07-17-2014 |
20140256127 | METHODS FOR REDUCING METAL OXIDE SURFACES TO MODIFIED METAL SURFACES USING A GASEOUS REDUCING ENVIRONMENT - Method and apparatus for reducing metal oxide surfaces to modified metal surfaces are disclosed. Metal oxide surfaces are reduced to form a film integrated with a metal seed layer on a substrate by exposing the metal oxide surfaces to a reducing gas atmosphere comprising radicals of a reducing gas species. The radicals of the reducing gas species can form from exposing the reducing gas species to ultraviolet radiation and/or a plasma. The substrate is maintained at a temperature below a temperature that produces agglomeration of the metal seed layer during exposure to the reducing gas atmosphere, such as below 150° C. for copper. In some embodiments, the reducing gas species can include at least one of hydrogen, ammonia, carbon monoxide, diborane, sulfite compounds, carbon and/or hydrocarbons, phosphites, and hydrazine. | 09-11-2014 |
20140256128 | METHOD AND APPARATUS FOR REMOTE PLASMA TREATMENT FOR REDUCING METAL OXIDES ON A METAL SEED LAYER - Method and apparatus for reducing metal oxide surfaces to modified metal surfaces are disclosed. By exposing a metal oxide surface to a remote plasma, the metal oxide surface on a substrate can be reduced to pure metal and the metal reflowed. A remote plasma apparatus can treat the metal oxide surface as well as cool, load/unload, and move the substrate within a single standalone apparatus. The remote plasma apparatus includes a processing chamber and a controller configured to provide a substrate having a metal seed layer in a processing chamber, form a remote plasma of a reducing gas species where the remote plasma includes radicals, ions, and/or ultraviolet (UV) radiation from the reducing gas species, and expose a metal seed layer of the substrate to the remote plasma to reduce oxide of the metal seed layer to metal and to reflow the metal. | 09-11-2014 |
20150072538 | METHOD AND APPARATUS FOR REMOTE PLASMA TREATMENT FOR REDUCING METAL OXIDES ON A METAL SEED LAYER - Method and apparatus for reducing metal oxide surfaces to modified metal surfaces are disclosed. By exposing a metal oxide surface to a remote plasma, the metal oxide surface on a substrate is reduced. A remote plasma apparatus can treat the metal oxide surface as well as cool, load/unload, and move the substrate within a single standalone apparatus. The remote plasma apparatus includes a processing chamber and a controller configured to provide a substrate having a metal seed layer in a processing chamber, move the substrate towards a substrate support in the processing chamber, form a remote plasma of a reducing gas species, expose a metal seed layer of the substrate to the remote plasma, and expose the substrate to a cooling gas. In some embodiments, the remote plasma apparatus is part of an electroplating apparatus. | 03-12-2015 |
20150299886 | METHOD AND APPARATUS FOR PREPARING A SUBSTRATE WITH A SEMI-NOBLE METAL LAYER - Method and apparatus for preparing a substrate with a semi-noble metal layer are disclosed. The substrate can be pretreated so that a metal oxide surface on the semi-noble metal layer can be reduced to a modified metal surface integrated with the semi-noble metal layer. The substrate can be pretreated using a remote plasma treatment. A copper seed layer can be formed on the semi-noble metal layer using either an acidic or alkaline bath with a plating solution including either at least two copper complexing agents with varying dentacity or a single hexadentate copper complexing agent that is in excess of the copper source. The copper complexing agents can include a hexadentate ligand and a bidentate ligand. In some embodiments, a bulk layer of copper can be subsequently deposited on the copper seed layer using an acidic bath. | 10-22-2015 |
20150376792 | ATMOSPHERIC PLASMA APPARATUS FOR SEMICONDUCTOR PROCESSING - Method and apparatus for treating a substrate prior to deposition using atmospheric plasma are disclosed. A substrate can be provided between a substrate support and a plasma distributor, where the plasma distributor includes one or more atmospheric plasma sources. The atmospheric plasma sources can generate plasma under atmospheric pressure, where the plasma can include radicals and ions of a process gas, such as a reducing gas species. The substrate can be exposed to the plasma under atmospheric pressure to treat the surface of the substrate, where atmospheric pressure can be between about 50 Torr and about 760 Torr. In some embodiments, substrate includes a metal seed layer having portions converted to oxide of a metal, where exposure to the plasma reduces the oxide of the metal and reflows the metal in the metal seed layer. | 12-31-2015 |