摘要:
Methods are disclosed that enhance the contrast between alignment targets and adjacent materials on a semiconductor wafer. According to a first embodiment, the TiN layer that is deposited during an earlier processing step is stripped away to enhance the reflectivity of the metal layer. According to a second embodiment, a reflective coating is added over the metal layer to enhance the reflectivity of the metal layer. According to a third embodiment, a reflective coating is added over the entire wafer to enhance the reflectivity of the metal layer. According to a fourth embodiment, an anti-reflective coating in a sandwich structure is added to reduce the reflectivity of the material adjacent the alignment targets. According to a fifth embodiment, an organic anti-reflective coating is added to reduce the reflectivity of the material adjacent the alignment targets. All of these embodiments result in a contrast between the alignment target and the adjacent material that is more consistent over variations in oxide thickness. The more uniform contrast makes it easier for the stepper system to identify the edges of the alignment targets, resulting in a more exact placement of the mask.
摘要:
The preferred embodiment of the present invention provides a method for defining three regions on a semiconductor substrate using a single masking step. The preferred embodiment uses a photoresist material having, simultaneously, both a positive tone and a negative tone response to exposure. This combination of materials can provide a new type of resist, which we call a hybrid resist. The hybrid resist comprises a positive tone component which acts at a first actinic energy level and a negative tone component which acts at a second actinic energy level, with the first and second actinic energy levels being separated by an intermediate range of actinic energy. When hybrid resist is exposed to actinic energy, areas of the resist which are subject to a full exposure cross link to form a negative tone line pattern, areas which are unexposed form remain photoactive and form a positive tone pattern, and areas which are exposed to intermediate amounts of radiation become soluble and wash away during development. This exposes a first region on the mask. By then blanket exposing the hybrid resist, the positive tone patterns become soluble and will wash away during development. This exposes a second region on the mask, with the third region still be covered by the hybrid resist. Thus, the preferred embodiment is able to define three regions using a single masking step, with no chance for overlay errors.
摘要:
A device architecture with embedded planar conductive ground and power planes in the device architecture. The apparatus includes a first conductive plane, a second conductive plane, a signal plane disposed between the first and second conductive planes, and a logic level disposed adjacent the first conductive plane and connected to the signal plane through at least one via in the conductive plane. The apparatus also includes a built-in alignment scheme. The invention includes a method for making the device and alignment architectures.
摘要:
According to the preferred embodiment, an antifuse structure and method for personalizing a semiconductor device is provided that overcomes the limitations of the prior art. The preferred embodiment antifuse comprises a two layer transformable insulator core between two electrodes. The transformable core is normally non-conductive but can be transformed into a conductive material by supplying a sufficient voltage across the electrodes. The two layer core preferably comprises an injector layer and a dielectric layer. The injector layer preferably comprises a two phase material such as silicon rich nitride or silicon rich oxide. Initially, the injector layer and dielectric layer are non-conductive. When a sufficient voltage is applied the core fuses together and becomes conductive.
摘要:
Methods are disclosed that enhance the contrast between alignment targets and adjacent materials on a semiconductor wafer. According to a first embodiment, the TiN layer that is deposited during an earlier processing step is stripped away to enhance the reflectivity of the metal layer. According to a second embodiment, a reflective coating is added over the metal layer to enhance the reflectivity of the metal layer. According to a third embodiment, a reflective coating is added over the entire wafer to enhance the reflectivity of the metal layer. According to a fourth embodiment, an anti-reflective coating in a sandwich structure is added to reduce the reflectivity of the material adjacent the alignment targets. According to a fifth embodiment, an organic anti-reflective coating is added to reduce the reflectivity of the material adjacent the alignment targets. All of these embodiments result in a contrast between the alignment target and the adjacent material that is more consistent over variations in oxide thickness. The more uniform contrast makes it easier for the stepper system to identify the edges of the alignment targets, resulting in a more exact placement of the mask.
摘要:
This describes a test pattern and method for measuring dimensional characteristics of features formed on a surface. This is realized and provided by forming a space, defined by the feature, in intersecting relationship with a pair of conductive lines of a test pattern configuration such that the lines are altered at the intersection with the space in accordance with the dimensions of that space, measuring the resistance of at least one of the lines in a region remote from the intersection with the space and the resistance of each line in the region of its intersection with the space, and comparing the resistance of the remote region with the resistances for the region of each of the lines where they intersect the space to thereby establish the position of, and at least one dimension of that space. A test structure wherein the spaced lines intersect the longitudinal ends of the space is utilized for determining the length and the longitudinal position of the space, and a test structure where lines intersect the lateral edges of the space is utilized for determining the width of and the lateral position of the space. For measuring the dimensional characteristics of a line feature, the above noted patterns are utilized, after first replicating the line as a space.