Abstract: Methods and systems are provided for fabricating a semiconductor device. An exemplary method involves forming a feature of a semiconductor device in a first region of a layer of material on a semiconductor substrate and forming a test structure in a second region of the layer of material. The test structure is formed concurrently to forming the feature, and a dimension of the feature is determined using the test structure.

Abstract: In sophisticated semiconductor devices, manufacturing techniques and etch masks may be formed on the basis of a mask layer stack which comprises an additional mask layer, which may receive an opening on the basis of lithography techniques. Thereafter, the width of the mask opening may be reduced by applying a selective deposition or growth process, which thus results in a highly uniform and well-controllable adjustment of the target width of the etch mask prior to performing the actual patterning process, for instance for forming sophisticated contact openings, via openings and the like.

Abstract: A method is provided including depositing a layer of material on a substrate, during deposition of the material, at a predetermined depth, laterally implanting a first dopant and a second dopant in the material, the second dopant being different from the first dopant, etching the material, during etching, detecting the positions and intensities of the first and second dopants, and calculating lateral homogeneity of the material in situ from the intensities of the first and second dopants.

Abstract: Integrated circuits having place-efficient capacitors and methods for fabricating the same are provided. A dielectric layer is formed overlying a conductive feature on a semiconductor substrate. A via opening is formed into the dielectric layer to expose a portion of the conductive feature. A partial opening is etched into the dielectric layer and positioned over the conductive feature. Etch resistant particles are deposited overlying the dielectric layer and in the partial opening. The dielectric layer is further etched using the etch resistant particles as an etch mask to extend the partial opening. A first conductive layer is formed overlying the extended partial opening and electrically contacting the conductive feature. A capacitor insulating layer is formed overlying the first conductive layer. A second conductive layer is formed overlying the insulating layer.

Abstract: Integrated circuits having place-efficient capacitors and methods for fabricating the same are provided. A dielectric layer is formed overlying a conductive feature on a semiconductor substrate. A via opening is formed into the dielectric layer to expose a portion of the conductive feature. A partial opening is etched into the dielectric layer and positioned over the conductive feature. Etch resistant particles are deposited overlying the dielectric layer and in the partial opening. The dielectric layer is further etched using the etch resistant particles as an etch mask to extend the partial opening. A first conductive layer is formed overlying the extended partial opening and electrically contacting the conductive feature. A capacitor insulating layer is formed overlying the first conductive layer. A second conductive layer is formed overlying the insulating layer.

Abstract: A capacitor is formed in nano channels in a conductive body. Embodiments include forming a source contact through a first inter layer dielectric (ILD), forming a conductive body on the first ILD, forming a second ILD on the conductive body, forming drain and gate contacts through the second ILD, conductive body, and first ILD, forming nano channels in the conductive body, forming an insulating layer in the channels, and metalizing the channels. An embodiment includes forming the nano channels by forming a mask on the second ILD, the mask having features with a pitch of 50 nanometers (nm) to 100 nm, etching the second ILD through the mask, etching the conductive body through the mask to a depth of 80% to 90% of the thickness of the conductive body, and removing the mask.

Abstract: Vertical contact structures, such as contact elements connected to semiconductor-based contact regions in device areas comprising densely-spaced gate electrode structures, are formed for given lithography and patterning capabilities by incorporating at least one additional dielectric layer of superior tapering behavior into the dielectric material system.

Abstract: Embodiments of a method for fabricating integrated circuits are provided. In one embodiment, the method includes the steps of depositing a dielectric layer over a semiconductor device, forming a plurality of trimmed hardmask structures at predetermined locations over the dielectric layer, embedding the plurality of trimmed hardmask structures in a surrounding hardmask layer, removing the plurality of trimmed hardmask structures to create a plurality of openings through the surrounding hardmask layer, and etching the dielectric layer through the plurality of openings to form a plurality of etch features therein.

Abstract: A semiconductor device is formed by implanting recess markers in a material during deposition and using the recess markers during etching of the material for precise in-situ removal rate definition and removal homogeneity-over-radius definition. An embodiment includes depositing a layer of material on a substrate, implanting first and second dopants in the material at first and second predetermined times during deposition of the material, etching the material, detecting the depths of the first and second dopants during etching, calculating the removal rate of the material in situ from the depths of the first and second dopants, and determining from the removal rate a stop position for etching.

Abstract: A semiconductor device is formed by implanting recess markers in a material during deposition and using the recess markers during etching of the material for precise in-situ removal rate definition and removal homogeneity-over-radius definition. An embodiment includes depositing a layer of material on a substrate, implanting first and second dopants in the material at first and second predetermined times during deposition of the material, etching the material, detecting the depths of the first and second dopants during etching, calculating the removal rate of the material in situ from the depths of the first and second dopants, and determining from the removal rate a stop position for etching.

Abstract: Analysis of chemical and physical characteristics of polymer species and etch residues caused in critical plasma-assisted etch processes for patterning material layers in semiconductor devices may be accomplished by removing at least a portion of these species on the basis of a probing material layer, which may be lifted-off from the patterned surface. The probing material layer may substantially suppress a chemical modification of the species of interest and may thus allow the examination of the initial status of these species.

Abstract: In complex semiconductor devices, the contact characteristics may be efficiently determined on the basis of a test structure which includes a combination of interconnect chain structures and a comb structure including gate electrode structures. Consequently, an increased amount of measurement information may be obtained on the basis of a reduced overall floor space of the test structure. In this manner, the complex manufacturing sequence for forming a contact level of a semiconductor device may be quantitatively estimated and monitored.

Abstract: A stress compensation region that may be appropriately positioned on a package substrate may compensate for or at least significantly reduce the thermally induced mechanical stress in a sensitive metallization system of a semiconductor die, in particular during the critical reflow process. For example, a stressor ring may be formed so as to laterally surround the chip receiving portion of the package substrate, wherein the stressor ring may efficiently compensate for the thermally induced deformation in the chip receiving portion.

Abstract: Thermally induced stress in a semiconductor die, i.e., in a complex metallization system thereof, may be reduced by “dividing” a package substrate into two or more substrate sections, which may have formed therebetween an appropriate stress buffer region, for instance a region of superior resiliency. In this case, the total deformation of the package substrate may be reduced, thereby also reducing the thermally induced stress forces in the complex metallization system of the semiconductor die. Hence, for a given size and complexity of a metallization system, an increased production yield and superior reliability may be achieved.

Abstract: In a semiconductor device, capacitors may be formed so as to be in direct contact with a transistor by using a shared transistor region, such as a drain region or a source region of closely spaced transistors, as one capacitor electrode, while the other capacitor electrode is provided in the form of a buried electrode in the dielectric material of the contact level. To this end, dielectric material may be deposited so as to reliably form a void, wherein, at any appropriate manufacturing stage, a capacitor dielectric material may be provided so as to separate the capacitor electrodes.

Abstract: An efficient patterning strategy may be applied when etching through a dielectric material system on the basis of two different etch chemistries. To this end, a conductive etch stop or barrier material may be formed in the opening prior to etching through the further dielectric layer of the material system, thereby substantially preserving the initial critical dimensions and avoiding etch damage. Thus, superior contact openings, via openings and the like may be formed on the basis of well-established etch chemistries.

Abstract: A contact level in a semiconductor device may be used for providing a capacitor that may be directly connected to a transistor, thereby providing a very space-efficient capacitor/transistor configuration. For example, superior dynamic RAM arrays may be formed on the basis of the capacitor/transistor configuration disclosed herein.

Abstract: During the fabrication of microstructure devices, such as integrated circuits, particles may be analyzed by displacing or removing the particles from the device surface and subsequently performing an analysis process. Consequently, a well-defined measurement environment may be established after removal of the particles, which may be accomplished on the basis of nanoprobes and the like. Hence, even critical surface areas may be monitored with respect to contamination and the like on the basis of well-established analysis techniques.

Abstract: By digitizing the UFM signal without using a lock-in amplifier, substantially all of the information initially contained in the UFM output signal may be maintained and may then be used for further data processing. Consequently, any type of model or evaluation algorithm may be used without being restricted to a very narrow bandwidth, as is the case in lock-in based techniques. The digitizing is performed on a real-time basis, wherein a complete UFM curve is digitized and stored for each scan position. In this way, quantitative meaningful values for specific surface-related characteristics with a nanometer resolution may be obtained.

Abstract: By digitizing the UFM signal without using a lock-in amplifier, substantially all of the information initially contained in the UFM output signal may be maintained and may then be used for further data processing. Consequently, any type of model or evaluation algorithm may be used without being restricted to a very narrow bandwidth, as is the case in lock-in based techniques. The digitizing is performed on a real-time basis, wherein a complete UFM curve is digitized and stored for each scan position. In this way, quantitative meaningful values for specific surface-related characteristics with a nanometer resolution may be obtained.