Abstract: Selective gas etching for self-aligned pattern transfer uses a first block and a separate second block formed in a sacrificial layer to transfer critical dimensions to a desired final layer using a selective gas etching process. The first block is a first hardmask material that can be plasma etched using a first gas, and the second block is a second hardmask material that can be plasma etched using a second gas separate from the first gas. The first hardmask material is not plasma etched using the second gas, and the second hardmask material is not plasma etched using the first gas.

Abstract: Selective gas etching for self-aligned pattern transfer uses a first block and a separate second block formed in a sacrificial layer to transfer critical dimensions to a desired final layer using a selective gas etching process. The first block is a first hardmask material that can be plasma etched using a first gas, and the second block is a second hardmask material that can be plasma etched using a second gas separate from the first gas. The first hardmask material is not plasma etched using the second gas, and the second hardmask material is not plasma etched using the first gas.

Abstract: A method for patterning self-aligned vias in a dielectric. The method includes forming a first trench partially through a hard mask, where the trench corresponds to a desired wiring path in the dielectric. The trench should be formed on a sub-lithographic scale. Then, form a second trench, also of a sub-lithographic scale, that intersects the first trench. The intersection forms a pattern extending through the depth of the hard mask, and corresponds to a via hole in the dielectric. The via hole is etched into the dielectric through the hard mask. Then the first trench is extended through the hard mask and the exposed area is etched to form the wiring path, which intersects the via hole. Conductive material is deposited to form a sub-lithographic via and wiring. This method may be used to form multiple vias of sub-lithographic proportions and with a sub-lithographic pitch.

Abstract: A method for patterning self-aligned vias in a dielectric. The method includes forming a first trench partially through a hard mask, where the trench corresponds to a desired wiring path in the dielectric. The trench should be formed on a sub-lithographic scale. Then, form a second trench, also of a sub-lithographic scale, that intersects the first trench. The intersection forms a pattern extending through the depth of the hard mask, and corresponds to a via hole in the dielectric. The via hole is etched into the dielectric through the hard mask. Then the first trench is extended through the hard mask and the exposed area is etched to form the wiring path, which intersects the via hole. Conductive material is deposited to form a sub-lithographic via and wiring. This method may be used to form multiple vias of sub-lithographic proportions and with a sub-lithographic pitch.

Abstract: A method for patterning self-aligned vias in a dielectric. The method includes forming a first trench partially through a hard mask, where the trench corresponds to a desired wiring path in the dielectric. The trench should be formed on a sub-lithographic scale. Form a second trench, also of a sub-lithographic scale, that intersects the first trench. The intersection forms a pattern extending through the depth of the hard mask, and corresponds to a via hole in the dielectric. The via hole is etched into the dielectric through the hard mask. The first trench is extended through the hard mask and the exposed area is etched to form the wiring path, which intersects the via hole. Conductive material is deposited to form a sub-lithographic via and wiring. This method may be used to form multiple vias of sub-lithographic proportions and with a sub-lithographic pitch.

Abstract: A tubular object is fabricated by a method comprising the steps of providing a first layer, forming a second layer on the first layer, and then patterning the second layer to form a raised feature with one or more sidewalls. Subsequently, the first layer is processed such that components of the first layer deposit on the one or more sidewalls of the raised feature.

Abstract: A feature is formed in an integrated circuit by providing one or more layers to be patterned, providing a first layer overlying the one or more layers to be patterned, and providing a second layer overlying the first layer. The second layer is patterned to form a raised feature with one or more sidewalls. Subsequently, the first layer is processed such that components of the first layer deposit on the one or more sidewalls of the raised feature to form a mask. The mask is used to pattern the one or more layers to be patterned.

Abstract: A PCM cell structure comprises a first electrode, a phase change element, and a second electrode, wherein the phase change element is inserted in between the first electrode and the second electrode and only the peripheral edge of the first electrode contacts the phase change element thereby reducing the contact area between the phase change element and the first electrode and thereby increasing the current density through the phase change element and effectively inducing the phase change at lower levels of current and reduced programming power.

Abstract: A PCM cell structure comprises a first electrode, a phase change element, and a second electrode, wherein the phase change element is inserted in between the first electrode and the second electrode and only the peripheral edge of the first electrode contacts the phase change element thereby reducing the contact area between the phase change element and the first electrode and thereby increasing the current density through the phase change element and effectively inducing the phase change at lower levels of current and reduced programming power.

Abstract: A Phase Change Memory (PCM) cell structure comprises both a lower electrode composed of a PCM layer and a conductive encapsulating upper electrode layer. The PCM layer is protected from damage by the conductive encapsulating layer. Electrical isolation between adjacent PCM cells is provided by high electrical resistance regions which were formed by modifying the conductivity of both the PCM layer and the conductive encapsulating upper electrode layer subsequent to deposition thereof.

Abstract: A Phase Change Memory (PCM) cell structure comprises both a lower electrode composed of a PCM layer and a conductive encapsulating upper electrode layer. The PCM layer is protected from damage by the conductive encapsulating layer. Electrical isolation between adjacent PCM cells is provided by high electrical resistance regions which were formed by modifying the conductivity of both the PCM layer and the conductive encapsulating upper electrode layer subsequent to deposition thereof.

Abstract: A feature is formed in an integrated circuit by providing one or more layers to be patterned, providing a first layer overlying the one or more layers to be patterned, and providing a second layer overlying the first layer. The second layer is patterned to form a raised feature with one or more sidewalls. Subsequently, the first layer is processed such that components of the first layer deposit on the one or more sidewalls of the raised feature to form a mask. The mask is used to pattern the one or more layers to be patterned.

Abstract: A tubular object is fabricated by a method comprising the steps of providing a first layer, forming a second layer on the first layer, and then patterning the second layer to form a raised feature with one or more sidewalls. Subsequently, the first layer is processed such that components of the first layer deposit on the one or more sidewalls of the raised feature.

Abstract: A method for forming a Phase Change Material (PCM) cell structure comprises forming both a lower electrode composed of a PCM layer and a conductive encapsulating upper electrode layer. The PCM is protected from damage by a conductive encapsulating layer. Electrical isolation between adjacent cells is provided by modifying the conductivity of both the PCM layer and the conductive encapsulating upper electrode layer subsequent to deposition thereof, thereby forming high electrical resistance regions between the cells.

Abstract: A PCM cell structure comprises a lower electrode composed of a Phase Change Memory (PCM) layer and a conductive encapsulating upper electrode layer. The PCM is protected from damage by a conductive encapsulating layer. Electrical isolation between adjacent cells is provided by modifying the conductivity of the PCM layer and the conductive encapsulating upper electrode layer subsequent to deposition.