Abstract: A copper-diffusion plug 21 is provided within a pore in dielectric layer over a copper signal line. By positioning the plug below a chalcogenide region, the plug is effective to block copper diffusion upwardly into the pore and into the chalcogenide region and thus to avoid adversely affecting the electrical characteristics of the chalcogenide region.

Abstract: A phase change memory formed by a plurality of phase change memory devices having a chalcogenide memory region extending over an own heater. The heaters have all a relatively uniform height. The height uniformity is achieved by forming the heaters within pores in an insulator that includes an etch stop layer and a sacrificial layer. The sacrificial layer is removed through an etching process such as chemical mechanical planarization. Since the etch stop layer may be formed in a repeatable way and is common across all the devices on a wafer, considerable uniformity is achieved in heater height. Heater height uniformity results in more uniformity in programmed memory characteristics.

Abstract: Small phase change memory cells may be formed by forming a segmented heater over a substrate. A stop layer may be formed over the heater layer and segmented with the heater layer. Then, sidewall spacers may be formed over the segmented heater to define an aperture between the sidewall spacers that may act as a mask for etching the stop layer over the segmented heater. As a result of the etching using the sidewall spacers as a mask, sublithographic pore may be formed over the heater. Phase change material may be formed within the pore.

Abstract: Small phase change memory cells may be formed by forming a segmented heater over a substrate. A stop layer may be formed over the heater layer and segmented with the heater layer. Then, sidewall spacers may be formed over the segmented heater to define an aperture between the sidewall spacers that may act as a mask for etching the stop layer over the segmented heater. As a result of the etching using the sidewall spacers as a mask, sublithographic pore may be formed over the heater. Phase change material may be formed within the pore.

Abstract: A dual resistance heater for a phase change material region is formed by depositing a resistive material. The heater material is then exposed to an implantation or plasma which increases the resistance of the surface of the heater material relative to the remainder of the heater material. As a result, the portion of the heater material approximate to the phase change material region is a highly effective heater because of its high resistance, but the bulk of the heater material is not as resistive and, thus, does not increase the voltage drop and the current usage of the device.

Abstract: A dual resistance heater for a phase change material region is formed by depositing a resistive material. The heater material is then exposed to an implantation or plasma which increases the resistance of the surface of the heater material relative to the remainder of the heater material. As a result, the portion of the heater material approximate to the phase change material region is a highly effective heater because of its high resistance, but the bulk of the heater material is not as resistive and, thus, does not increase the voltage drop and the current usage of the device.

Abstract: Semiconductor memory devices and methods to fabricate thereof are described. A first gate base is formed on a first insulating layer on a substrate. A first gate fin is formed on the first gate base. The first gate fin has a top and sidewalls. Next, a second insulating layer is formed on the top and sidewalls of the first gate fin and portions of the first gate base. A second gate is formed on the second insulating layer. Source and drain regions are formed in the substrate at opposite sides of the first gate base. In one embodiment, the first gate fin includes an undoped polysilicon and the first gate base includes an n-type polysilicon. In another embodiment, the first gate fin includes an undoped amorphous silicon and the first gate base includes an n-type amorphous silicon.

Abstract: Small phase change memory cells may be formed by forming a segmented heater over a substrate. A stop layer may be formed over the heater layer and segmented with the heater layer. Then, sidewall spacers may be formed over the segmented heater to define an aperture between the sidewall spacers that may act as a mask for etching the stop layer over the segmented heater. As a result of the etching using the sidewall spacers as a mask, sublithographic pore may be formed over the heater. Phase change material may be formed within the pore.

Abstract: Both a chalcogenide select device and a chalcogenide memory element are formed within vias within dielectrics. As a result, the chalcogenides is effectively trapped within the vias and no glue or adhesion layer is needed. Moreover, delamination problems are avoided. A lance material is formed within the same via with the memory element. In one embodiment, the lance material is made thinner by virtue of the presence of a sidewall spacer; in another embodiment no sidewall spacer is utilized. A relatively small area of contact between the chalcogenide used to form a memory element and the lance material is achieved by providing a pin hole opening in a dielectric, which separates the chalcogenide and the lance material.

Abstract: A phase change material may be formed within a trench in a first layer to form a damascene memory element and in an overlying layer to form a threshold device. Below the first layer may be a wall heater. The wall heater that heats the overlying phase change material may be formed in a U-shape in some embodiments of the present invention. The phase change material for the memory element may be elongated in one direction to provide greater alignment tolerances with said heater and said threshold device.

Abstract: A copper-diffusion plug 21 is provided within a pore in dielectric layer over a copper signal line. By positioning the plug below a chalcogenide region, the plug is effective to block copper diffusion upwardly into the pore and into the chalcogenide region and thus to avoid adversely affecting the electrical characteristics of the chalcogenide region.

Abstract: A phase change memory cell may include two or more stacked or unstacked series connected memory elements. The cell has a higher, adjustable threshold voltage. A copper diffusion plug may be provided within a pore over a copper line. By positioning the plug below the subsequent chalcogenide layer, the plug may be effective to block copper diffusion upwardly into the pore and into the chalcogenide material. Such diffusion may adversely affect the electrical characteristics of the chalcogenide layer.

Abstract: A phase change memory formed by a plurality of phase change memory devices having a chalcogenide memory region extending over an own heater. The heaters have all a relatively uniform height. The height uniformity is achieved by forming the heaters within pores in an insulator that includes an etch stop layer and a sacrificial layer. The sacrificial layer is removed through an etching process such as chemical mechanical planarization. Since the etch stop layer may be formed in a repeatable way and is common across all the devices on a wafer, considerable uniformity is achieved in heater height. Heater height uniformity results in more uniformity in programmed memory characteristics.

Abstract: According to an embodiment of the invention, a flash memory cell includes a first gate stack and a second gate stack having a film deposited across the gap between the first and second gate stacks so that the film creates a void between the first and second gate stacks. Dielectric materials may be used to reduce conductivity between the two stacks. A dielectric material that is resistant to conductivity has a low dielectric constant (k). The lowest-k dielectric material is air, which has a dielectric constant of approximately 1. By creating a void between the two gate stacks, the least conductive material (air) is left filling the space between the gate stacks, and the likelihood of parasitic coupling of two adjacent floating gates is substantially reduced.

Abstract: Semiconductor memory devices and methods to fabricate thereof are described. A first gate base is formed on a first insulating layer on a substrate. A first gate fin is formed on the first gate base. The first gate fin has a top and sidewalls. Next, a second insulating layer is formed on the top and sidewalls of the first gate fin and portions of the first gate base. A second gate is formed on the second insulating layer. Source and drain regions are formed in the substrate at opposite sides of the first gate base. In one embodiment, the first gate fin includes an undoped polysilicon and the first gate base includes an n-type polysilicon. In another embodiment, the first gate fin includes an undoped amorphous silicon and the first gate base includes an n-type amorphous silicon.

Abstract: Semiconductor memory devices and methods to fabricate thereof are described. A first gate base is formed on a first insulating layer on a substrate. A first gate fin is formed on the first gate base. The first gate fin has a top and sidewalls. Next, a second insulating layer is formed on the top and sidewalls of the first gate fin and portions of the first gate base. A second gate is formed on the second insulating layer. Source and drain regions are formed in the substrate at opposite sides of the first gate base. In one embodiment, the first gate fin includes an undoped polysilicon and the first gate base includes an n-type polysilicon. In another embodiment, the first gate fin includes an undoped amorphous silicon and the first gate base includes an n-type amorphous silicon.

Abstract: According to an embodiment of the invention, a flash memory cell includes a first gate stack and a second gate stack having a film deposited across the gap between the first and second gate stacks so that the film creates a void between the first and second gate stacks. Dielectric materials may be used to reduce conductivity between the two stacks. A dielectric material that is resistant to conductivity has a low dielectric constant (k). The lowest-k dielectric material is air, which has a dielectric constant of approximately 1. By creating a void between the two gate stacks, the least conductive material (air) is left filling the space between the gate stacks, and the likelihood of parasitic coupling of two adjacent floating gates is substantially reduced.

Abstract: Both a chalcogenide select device (24, 120) and a chalcogenide memory element (40, 130) are formed within vias within dielectrics (18, 22). As a result, the chalcogenides is effectively trapped within the vias and no glue or adhesion layer is needed. Moreover, delamination problems are avoided. A lance material (30) is formed within the same via (31) with the memory element (40, 130). In one embodiment, the lance material is made thinner by virtue of the presence of a sidewall spacer (28); in another embodiment no sidewall spacer is utilized. A relatively small area of contact between the chalcogenide (40) used to form a memory element (130) and the lance material (30) is achieved by providing a pin hole opening in a dielectric (34), which separates the chalcogenide and the lance material.

Abstract: A phase change memory may be formed to have a dimension that is sub-lithographic in one embodiment by forming a surface feature over the phase change material, and coating the surface feature with a mask of sub-lithographic dimensions. The horizontal portions of the mask and the surface feature may then be removed and the remaining portions of the mask may be used to define a dimension of said phase change material. Another dimension of the phase change material may be defined using an upper electrode extending over said phase change material as a mask to etch the phase change material.

Abstract: A phase change memory may be formed to have a dimension that is sub-lithographic in one embodiment by forming a surface feature over the phase change material, and coating the surface feature with a mask of sub-lithographic dimensions. The horizontal portions of the mask and the surface feature may then be removed and the remaining portions of the mask may be used to define a dimension of said phase change material. Another dimension of the phase change material may be defined using an upper electrode extending over said phase change material as a mask to etch the phase change material.