Abstract: Method for processing at least one spacer structure in a manufacturing process of a semiconductor device, wherein the at least one spacer structure is subjected to at least one etch process step with an isotropic component and the spacer structure comprises at least one point on the surface with a large solid angle opening towards the environment. Method of manufacturing an integrated circuit, including a regional removal of a spacer structure, wherein the removal is determined by a pattern density in the vicinity of the spacer structure.

Abstract: A semiconductor device according to an aspect of the invention includes a semiconductor substrate, and a capacitor that is provided above the semiconductor substrate and is configured such that a dielectric film is sandwiched between a lower electrode and an upper electrode, the dielectric film being formed of an ABO3 perovskite-type oxide that includes at least one of Pb, Ba and Sr as an A-site element and at least one of Zr, Ti, Ta, Nb, Mg, W, Fe and Co as a B-site element, wherein a radius of curvature of a sidewall of the capacitor, when viewed from above or in a film thickness direction, is 250 [nm] or less, and a length of an arc with the radius of curvature is {250 [nm]×?/6 [rad]} or less.

Abstract: Ferrocapacitors having a vertical structure are formed by a process in which a ferroelectric layer is deposited over an insulator. In a first etching stage, the ferroelectric material is etched to form openings in it, leaving the insulating layer substantially intact. Then a conductive layer is deposited into the openings formed in the ferroelectric layer, forming electrodes on the sides of the openings. Further etching is performed to form gaps in the Al2O3 layer, for making connections to conductive elements beneath it. Thus, by the time the second etching step is performed; there are already electrodes overlying the sides of the ferroelectric material, without insulating fences in between.

Abstract: A semiconductor device according to an aspect of the invention comprises a semiconductor substrate, and a capacitor that is provided above the semiconductor substrate and is configured such that a dielectric film is sandwiched between a lower electrode and an upper electrode, the dielectric film being formed of an ABO3 perovskite-type oxide that includes at least one of Pb, Ba and Sr as an A-site element and at least one of Zr, Ti, Ta, Nb, Mg, W, Fe and Co as a B-site element, wherein a radius of curvature of a side wall of the capacitor, when viewed from above or in a film thickness direction, is 250 [nm] or less, and a length of an arc with the radius of curvature is {250 [nm]×?/6 [rad]} or more.

Abstract: A gate electrode stack is disposed on a substrate in a semiconductor device. A gate conductor includes at least one layer of polysilicon and at least one layer of poly-Si1?x,Gex material. The invention is also concerned with a process. This structure can be etched effectively since an end point detection is enabled.

Abstract: A method of etching a ferroelectric device 100 having a ferroelectric layer 112 between a top and a bottom electrode 114, 108 is disclosed herein. Hardmasks 116, 118 are deposited on the top electrode 114, two or more hardmasks being spaced apart by narrow first regions 115 and spaced apart from other hardmasks by wider second regions 117. The top electrode 114 and ferroelectric layer 112 are then etched to pattern the top electrode 114 thus forming capacitors 102, 104, and the bottom electrode 108 is etched by a process in which the second regions are etched more slowly than the second regions. Those capacitors having a first region between them have a common bottom electrode 108, but in the second regions the bottom electrode is severed. To pattern the bottom electrode 108, a fluorine-based chemistry followed thereafter by a CO-based chemistry are used in a two step etching process.

Abstract: A ferroelectric capacitor device comprises a substrate, a contact plug passing through the substrate, a first electrode formed on the substrate, the first electrode being electrically connected to said plug, a ferroelectric layer formed on the first electrode, a second electrode formed on the ferroelectric layer, one or more first encapsulation layers on the second electrode, the encapsulation layers extending over the device, and one or more hydrogen storage material layers on the encapsulation layers. One or more second encapsulation layers may be formed on the one or more hydrogen storage material layers.

Abstract: The present invention provides a ferroelectric device relatively free of fences by using a hardmask having high etching selectivity relative to an underlying barrier layer. The present invention also includes a method for suppressing the fences clinging to the sidewalls of ferroelectric devices. Additionally, the present invention provides a ferroelectric device having a hardmask relatively thin compared to an underlying barrier layer when compared to prior art devices.

Abstract: The present invention provides a sidewall oxygen diffusion barrier and a method for fabricating the sidewall oxygen diffusion barrier that reduces the diffusion of oxygen into contact plugs during a CW hole reactive ion etch of a ferroelectric capacitor of an FeRAM device. In one embodiment the sidewall barrier is formed from a substrate fence. In another embodiment, the sidewall barrier is formed by etching back an oxygen barrier.

Abstract: An Iridium barrier layer is between a contact plug and a bottom electrode of a capacitor. Etching is performed to pattern the bottom electrode and barrier layer using a fluorine-based recipe resulting in the formation of a first fence clinging to the sidewalls. Next the remaining barrier layer is etched using a CO-based recipe. A second fence is formed clinging to and structurally supported by the first fence. At the same time, the CO-based recipe etches away a substantial portion of the first fence to remove the structural support provided to the second fence. The second fence is therefore lifted-off from the sidewalls leaving the sidewalls substantially free of clinging fences. The etched barrier layer has a sidewall transition. The sidewalls have a relatively low taper angle above the sidewall transition and a relatively steep taper angle below the sidewall transition.

Abstract: A method for fabricating a device and a device, such as a ferroelectric capacitor, having a substrate, a contact plug through the substrate, a first barrier layer on the substrate, a first electrode on the first barrier layer, a dielectric layer on the first electrode, and a second electrode on the dielectric layer, comprises etching the second electrode and the dielectric layer of the device using a first hardmask, to shape the second electrode and the dielectric layer. The first hardmask is then removed and one or more encapsulating layers are applied to the second electrode and the dielectric layer. A further hardmask is applied to the one or more encapsulating layers. The first electrode is then etched according to the second hardmask down to the first barrier layer and the second hardmask is then removed from the one or more encapsulating layers.

Abstract: A ferroelectric device includes a bottom electrode on which are formed ferrocapacitor elements and, over the ferroelectric elements, top electrodes. The bottom electrodes are connected to lower layers of the device via conductive plugs, and the plugs and bottom electrodes are spaced apart by barrier elements of Ir and/or IrO2. The barrier elements are narrower than the bottom electrode elements, and are formed by a separate etching process. This means that Ir fences are not formed during the etching of the bottom electrode. Also, little Ir and/or IrO2 diffuses through the bottom electrode to the ferroelectric elements, and therefore there is little risk of damage to the ferroelectric material.

Abstract: A ferroelectric capacitor device, such as an FeRAM device is formed by forming a substrate extending in a first plane and comprising a number of layers of material, forming a hard mask layer on the substrate and forming a first layer of a first material on the hard mask layer. The hard mask shape is then defined by etching the hard mask layer. A second layer of the first material is deposited on the etched hard mask layer. The deposited second layer has one or more side surfaces extending substantially perpendicular to the plane of the substrate. The second layer and the number of layers forming the substrate are then etched to shape the ferroelectric capacitor device.

Abstract: A capacitor structure having a capacitor with a top electrode, a bottom electrode, and a capacitor dielectric layer between the top and bottom electrodes is disclosed. The capacitor includes upper and lower portions. The demarcation between the upper and lower portion is located between top and bottom surfaces of the capacitor dielectric layer. A dielectric layer is provided on the sidewalls of the upper portion of the capacitor to prevent shorting between the electrodes that can be caused by a conductive fence formed during processing.

Abstract: A vertical capacitor of an FeRAM device is formed by depositing conductive material and etching it to form electrodes, which are located over openings in an insulating layer so that they are electrically connected to lower levels of the structure. A layer of ferroelectric material is formed on the sides of the electrodes, and etched to a desired, uniform thickness. Conductive material is deposited over the ferroelectric material to form a uniform surface onto which another insulating layer can be deposited. Since this process does not include etching of an insulating layer at a time between the formation of the electrodes and the deposition of the ferroelectric material, no fences of insulating material are formed between them. The geometry can be accurately controlled, to give uniform electric fields and reliable operating parameters.

Abstract: Ferrocapacitors having a vertical structure are formed by a process in which a ferroelectric layer is deposited over an insulator. In a first etching stage, the ferroelectric material is etched to form openings in it, leaving the insulating layer substantially intact. Then a conductive layer is deposited into the openings formed in the ferroelectric layer, forming electrodes on the sides of the openings. Further etching is performed to form gaps in the Al2O3 layer, for making connections to conductive elements beneath it. Thus, by the time the second etching step is performed; there are already electrodes overlying the sides of the ferroelectric material, without insulating fences in between.

Abstract: A ferroelectric capacitor device, such as an FeRAM device is formed by forming a substrate extending in a first plane and comprising a number of layers of material, forming a hard mask layer on the substrate and forming a first layer of a first material on the hard mask layer. The hard mask shape is then defined by etching the hard mask layer. A second layer of the first material is deposited on the etched hard mask layer. The deposited second layer has one or more side surfaces extending substantially perpendicular to the plane of the substrate. The second layer and the number of layers forming the substrate are then etched to shape the ferroelectric capacitor device.

Abstract: A method for fabricating a device and a device, such as a ferroelectric capacitor, having a substrate, a contact plug through the substrate, a first barrier layer on the substrate, a first electrode on the first barrier layer, a dielectric layer on the first electrode, and a second electrode on the dielectric layer, comprises etching the second electrode and the dielectric layer of the device using a first hardmask, to shape the second electrode and the dielectric layer. The first hardmask is then removed and one or more encapsulating layers are applied to the second electrode and the dielectric layer. A further hardmask is applied to the one or more encapsulating layers. The first electrode is then etched according to the second hardmask down to the first barrier layer and the second hardmask is then removed from the one or more encapsulating layers.

Abstract: A device and method for fabricating a device comprises forming a substrate and forming a contact plug through the substrate. A first electrode is formed on the substrate and a dielectric layer is formed on the first electrode. A second electrode is formed on the ferroelectric layer and an interlayer dielectric layer is applied to the second electrode and exposed surfaces of the first electrode and the ferroelectric layer. The interlayer dielectric layer is subjected to a chemical mechanical polishing process to expose a surface of the second electrode and a metal layer is deposited onto the polished interlayer dielectric layer and the exposed surface of the second electrode. The metal layer is then etched to provide an interconnection pattern to the second electrode.

Abstract: A ferroelectric capacitor is fabricated using a noble metal hardmask. A hardmask is deposited on a top electrode of a capacitor stack comprising a ferroelectric layer sandwiched between the top electrode and a bottom electrode. The top electrode is patterned according to the pattern of the hardmask by etching at a first temperature. The top electrode serves as the noble metal hardmask and the ferroelectric layer is patterned according to the pattern of the top electrode at a second temperature lower than the first temperature, resulting in the top electrode having sidewalls beveled relative to a top surface of the top electrode etching. The bottom electrode is etched at a third temperature to form the capacitor.