Abstract: The invention is related to methods and apparatus for providing a resistance variable memory element with improved data retention and switching characteristics. According to one embodiment of the invention, a resistance variable memory element is provided having at least one silver-selenide layer in between two glass layers, wherein at least one of the glass layers is a chalcogenide glass, preferably having a GexSe100−x composition. According to another embodiment of the invention, a resistance variable memory element is provided having at least one silver-selenide layer in between chalcogenide glass layers and further having a silver layer above at least one of said chalcogenide glass layers and a conductive adhesion layer above said silver layer.

Abstract: Methods of forming metal-doped chalcogenide layers and devices containing such doped chalcogenide layers include using a plasma to induce diffusion of metal into a chalcogenide layer concurrently with metal deposition. The plasma contains at least one noble gas of low atomic weight, such as neon or helium. The plasma has a sputter yield sufficient to sputter a metal target and a UV component of its emitted spectrum sufficient to induce diffusion of the sputtered metal into the chalcogenide layer. Using such methods, a conductive layer can be formed on the doped chalcogenide layer in situ. In integrated circuit devices, such as non-volatile chalcogenide memory devices, doping of the chalcogenide layer concurrently with metal deposition and formation of a conductive layer in situ with the doping of the chalcogenide layer reduces contamination concerns and physical damage resulting from moving the device substrate from tool to tool, thus facilitating improved device reliability.

Abstract: A method of forming a programmable conductor memory cell array is disclosed wherein metal and chalcogenide glass are co-sputtered to fill an array of cell vias in a prepared substrate. The prepared substrate is heated above room temperature before the metal and chalcogenide glass film is deposited, and the heating is maintained throughout the deposition. The resulting metal/chalcogenide glass film has good homogeneity, a desired ratio of components, and has a regular surface.

Abstract: A multi layered copper bond pad for a semiconductor die which inhibits formation of copper oxide is disclosed. A small dose of titanium is implanted in the copper surface. The implanted titanium layer suppresses the copper oxide growth in the copper bond pad by controlling the concentration of vacancies available to the copper ion transport. An interconnect structure such as a wire bond or a solder ball may be attached to the copper-boron layer to connect the semiconductor die to a lead frame or circuit support structure. In another embodiment, a titanium-aluminum passivation layer for copper surfaces is also disclosed. The titanium-aluminum layer is annealed to form a titanium-aluminum-copper alloy. The anneal may be done in a nitrogen environment to form a titanium-aluminum-copper-nitrogen alloy.

Abstract: Methods of forming metal-doped chalcogenide layers and devices containing such doped chalcogenide layers include using a plasma to induce diffusion of metal into a chalcogenide layer concurrently with metal deposition. The plasma contains at least one noble gas of low atomic weight, such as neon or helium. The plasma has a sputter yield sufficient to sputter a metal target and a UV component of its emitted spectrum sufficient to induce diffusion of the sputtered metal into the chalcogenide layer. Using such methods, a conductive layer can be formed on the doped chalcogenide layer in situ. In integrated circuit devices, such as non-volatile chalcogenide memory devices, doping of the chalcogenide layer concurrently with metal deposition and formation of a conductive layer in situ with the doping of the chalcogenide layer reduces contamination concerns and physical damage resulting from moving the device substrate from tool to tool, thus facilitating improved device reliability.

Abstract: A method of forming a programmable conductor memory cell array is disclosed wherein metal and chalcogenide glass are co-sputtered to fill an array of cell vias in a prepared substrate. The prepared substrate is heated above room temperature before the metal and chalcogenide glass film is deposited, and the heating is maintained throughout the deposition. The resulting metal/chalcogenide glass film has good homogeneity, a desired ratio of components, and has a regular surface.

Abstract: A method of sputter depositing silver selenide and controlling the stoichiometry and nodular defect formations of a sputter deposited silver-selenide film. The method includes depositing silver-selenide using a sputter deposition process at a pressure of about 0.3 mTorr to about 10 mTorr. In accordance with one aspect of the invention, an RF sputter deposition process may be used preferably at pressures of about 2 mTorr to about 3 mTorr. In accordance with another aspect of the invention, a pulse DC sputter deposition process may be used preferably at pressures of about 4 mTorr to about 5 mTorr.

Abstract: A method of fabricating a glass containing target for sputter deposition of a glass onto a substrate. The method includes synthesizing a glass from pure chemical element materials and then forming the synthesized glass into a powder, which is then used to form a glass containing target. In accordance with one aspect of the invention, the glass containing target may be used for sputter deposition of a thin coating of glass on a substrate. In exemplary embodiments, the glass is a chalcogenide glass target useful in fabricating memory devices.

Abstract: The present invention is related to methods and apparatus that allow a chalcogenide glass such as germanium selenide (GeXSe1-X) to be doped with a metal such as silver, copper, or zinc without utilizing an ultraviolet (UV) photodoping step to dope the chalcogenide glass with the metal. The chalcogenide glass doped with the metal can be used to store data in a memory device. Advantageously, the systems and methods co-sputter the metal and the chalcogenide glass and allow for relatively precise and efficient control of a constituent ratio between the doping metal and the chalcogenide glass. Further advantageously, the systems and methods enable the doping of the chalcogenide glass with a relatively high degree of uniformity over the depth of the formed layer of chalcogenide glass and the metal. Also, the systems and methods allow a metal concentration to be varied in a controlled manner along the thin film depth.

Abstract: A method of forming a programmable conductor memory cell array is disclosed wherein metal and chalcogenide glass are co-sputtered to fill an array of cell vias in a prepared substrate. The prepared substrate is heated above room temperature before the metal and chalcogenide glass film is deposited, and the heating is maintained throughout the deposition. The resulting metal/chalcogenide glass film has good homogeneity, a desired ratio of components, and has a regular surface.

Abstract: The present invention provides methods of producing an anti-reflective layer on a semiconductor wafer/device and wafers/devices including that anti-reflective layer. The anti-reflective layer is produced by annealing layers of titanium and aluminum on a wafer/device to provide a roughened surface that significantly reduces reflectivity to improve the accuracy and definition provided by optical lithography processes.

Abstract: A multi layered copper bond pad for a semiconductor die which inhibits formation of copper oxide is disclosed. A small dose of titanium is implanted in the copper surface. The implanted titanium layer suppresses the copper oxide growth in the copper bond pad by controlling the concentration of vacancies available to the copper ion transport. An interconnect structure such as a wire bond or a solder ball may be attached to the copper-boron layer to connect the semiconductor die to a lead frame or circuit support structure. In another embodiment, a titanium-aluminum passivation layer for copper surfaces is also disclosed. The titanium-aluminum layer is annealed to form a titanium-aluminum-copper alloy. The anneal may be done in a nitrogen environment to form a titanium-aluminum-copper-nitrogen alloy.

Abstract: Methods of forming metal-doped chalcogenide layers and devices containing such doped chalcogenide layers include using a plasma to induce diffusion of metal into a chalcogenide layer concurrently with metal deposition. The plasma contains at least one noble gas of low atomic weight, such as neon or helium. The plasma has a sputter yield sufficient to sputter a metal target and a UV component of its emitted spectrum sufficient to induce diffusion of the sputtered metal into the chalcogenide layer. Using such methods, a conductive layer can be formed on the doped chalcogenide layer in situ. In integrated circuit devices, such as non-volatile chalcogenide memory devices, doping of the chalcogenide layer concurrently with metal deposition and formation of a conductive layer in situ with the doping of the chalcogenide layer reduces contamination concerns and physical damage resulting from moving the device substrate from tool to tool, thus facilitating improved device reliability.

Abstract: A multi layered copper bond pad for a semiconductor die which inhibits formation of copper oxide is disclosed. A small dose of titanium is implanted in the copper surface. The implanted titanium layer suppresses the copper oxide growth in the copper bond pad by controlling the concentration of vacancies available to the copper ion transport. An interconnect structure such as a wire bond or a solder ball may be attached to the copper-boron layer to connect the semiconductor die to a lead frame or circuit support structure. In another embodiment, a titanium-aluminum passivation layer for copper surfaces is also disclosed. The titanium-aluminum layer is annealed to form a titanium-aluminum-copper alloy. The anneal may be done in a nitrogen environment to form a titanium-aluminum-copper-nitrogen alloy.

Abstract: Methods of forming metal-doped chalcogenide layers and devices containing such doped chalcogenide layers include using a plasma to induce diffusion of metal into a chalcogenide layer concurrently with metal deposition. The plasma contains at least one noble gas of low atomic weight, such as neon or helium. The plasma has a sputter yield sufficient to sputter a metal target and a UV component of its emitted spectrum sufficient to induce diffusion of the sputtered metal into the chalcogenide layer. Using such methods, a conductive layer can be formed on the doped chalcogenide layer in situ. In integrated circuit devices, such as non-volatile chalcogenide memory devices, doping of the chalcogenide layer concurrently with metal deposition and formation of a conductive layer in situ with the doping of the chalcogenide layer reduces contamination concerns and physical damage resulting from moving the device substrate from tool to tool, thus facilitating improved device reliability.

Abstract: Methods of forming metal-doped chalcogenide layers and devices containing such doped chalcogenide layers include using a plasma to induce diffusion of metal into a chalcogenide layer concurrently with metal deposition. The plasma contains at least one noble gas of low atomic weight, such as neon or helium. The plasma has a sputter yield sufficient to sputter a metal target and a UV component of its emitted spectrum sufficient to induce diffusion of the sputtered metal into the chalcogenide layer. Using such methods, a conductive layer can be formed on the doped chalcogenide layer in situ. In integrated circuit devices, such as non-volatile chalcogenide memory devices, doping of the chalcogenide layer concurrently with metal deposition and formation of a conductive layer in situ with the doping of the chalcogenide layer reduces contamination concerns and physical damage resulting from moving the device substrate from tool to tool, thus facilitating improved device reliability.

Abstract: In one aspect the invention includes a method of protecting aluminum within an aluminum-comprising layer from electrochemical degradation during semiconductor processing comprising, providing a material within the layer having a lower reduction potential than aluminum. In another aspect, the invention includes a semiconductor processing method of forming and processing an aluminum-comprising mass, comprising: a) forming the aluminum-comprising layer mass to comprise a material having a lower reduction potential than aluminum; and b) exposing the aluminum-comprising mass to an electrolytic substance, the material protecting aluminum within the aluminum-comprising layer from electrochemical degradation during the exposing. In yet another aspect, the invention includes an aluminum-comprising layer over or within a semiconductor wafer substrate and comprising a material having a lower reduction potential than aluminum.

Abstract: Methods are provided for selective formation of oxidation-resistant caps for conductive plugs in semiconductor device fabrication. One embodiment of the present invention forms a sacrificial layer over a recessed polysilicon plug. The sacrificial layer is readily planarized using chemical mechanical planarization to isolate the cap within a recessed via. Then, an immersion plating process is used to replace the atoms of the sacrificial layer with atoms of a desired metal, such as platinum, thereby creating a metal cap isolated within the via. The advantages of planarization to isolate material within recessed via are thus obtained without having to planarize or otherwise etch the desired metal. The cap layer can be further reacted to form a barrier compound prior to forming a capacitor over the plug. Advantageously, the plug structure resists oxidation during fabrication of overlying capacitors that incorporate high dielectric constant materials.

Abstract: A copper interconnect structure is disclosed as comprising a copper layer and an aluminum nitride layer formed over the copper layer. The aluminum nitride layer passivates the copper layer surface and enhances the thermal conductivity of a semiconductor substrate by radiating heat from the substrate as well as from the copper layer.

Abstract: Methods are provided for selective formation of oxidation-resistant caps for conductive plugs in semiconductor device fabrication. One embodiment of the present invention forms a sacrificial layer over a recessed polysilicon plug. The sacrificial layer is readily planarized using chemical mechanical planarization to isolate the cap within a recessed via. Then, an immersion plating process is used to replace the atoms of the sacrificial layer with atoms of a desired metal, such as platinum, thereby creating a metal cap isolated within the via. The advantages of planarization to isolate material within recessed via are thus obtained without having to planarize or otherwise etch the desired metal. The cap layer can be further reacted to form a barrier compound prior to forming a capacitor over the plug. Advantageously, the plug structure resists oxidation during fabrication of overlying capacitors that incorporate high dielectric constant materials.