Abstract: A method of forming dummy structures and an overlay mark protection zone over an active layer zone based on the shape of an overlay mark and the resulting device are provided. Embodiments include determining a size and a shape of an overlay mark; determining a size and a shape of an overlay mark protection zone based on the shape of the overlay mark; determining a shape of a plurality of dummy structures based on the shape of the overlay mark; determining a size and a shape of an active layer zone based on the size and the shape of the overlay mark and the plurality of dummy structures; forming the active layer zone in an active layer of a semiconductor substrate; forming the overlay mark and the plurality of dummy structures over the active layer zone in a poly layer of the semiconductor substrate; and planarizing the poly layer.

Abstract: A method of forming dummy structures and an overlay mark protection zone over an active layer zone based on the shape of an overlay mark and the resulting device are provided. Embodiments include determining a size and a shape of an overlay mark; determining a size and a shape of an overlay mark protection zone based on the shape of the overlay mark; determining a shape of a plurality of dummy structures based on the shape of the overlay mark; determining a size and a shape of an active layer zone based on the size and the shape of the overlay mark and the plurality of dummy structures; forming the active layer zone in an active layer of a semiconductor substrate; forming the overlay mark and the plurality of dummy structures over the active layer zone in a poly layer of the semiconductor substrate; and planarizing the poly layer.

Abstract: A method of forming dummy structures and an overlay mark protection zone over an active layer zone based on the shape of an overlay mark and the resulting device are provided. Embodiments include determining a size and a shape of an overlay mark; determining a size and a shape of an overlay mark protection zone based on the shape of the overlay mark; determining a shape of a plurality of dummy structures based on the shape of the overlay mark; determining a size and a shape of an active layer zone based on the size and the shape of the overlay mark and the plurality of dummy structures; forming the active layer zone in an active layer of a semiconductor substrate; forming the overlay mark and the plurality of dummy structures over the active layer zone in a poly layer of the semiconductor substrate; and planarizing the poly layer.

Abstract: A method of forming dummy structures and an overlay mark protection zone over an active layer zone based on the shape of an overlay mark and the resulting device are provided. Embodiments include determining a size and a shape of an overlay mark; determining a size and a shape of an overlay mark protection zone based on the shape of the overlay mark; determining a shape of a plurality of dummy structures based on the shape of the overlay mark; determining a size and a shape of an active layer zone based on the size and the shape of the overlay mark and the plurality of dummy structures; forming the active layer zone in an active layer of a semiconductor substrate; forming the overlay mark and the plurality of dummy structures over the active layer zone in a poly layer of the semiconductor substrate; and planarizing the poly layer.

Abstract: Methods for fabricating integrated circuits with improved patterning schemes are provided. In an embodiment, a method for fabricating an integrated circuit includes depositing an interlayer dielectric material overlying a semiconductor substrate. Further, the method includes forming a patterned hard mask overlying the interlayer dielectric material. Also, the method forms an organic planarization layer overlying the patterned hard mask and contacting portions of the interlayer dielectric material. The method patterns the organic planarization layer using an extreme ultraviolet (EUV) lithography process. The method also includes etching the interlayer dielectric material using the patterned hard mask and organic planarization layer as a mask to form vias in the interlayer dielectric material.

Abstract: A method for fabricating integrated circuits includes fabricating an EUV mask by providing a photomask having a border region. A photoresist is formed over the photomask and has a border region overlying the border region of the photomask. The method exposes an inner portion and an outer portion of the photoresist border region. The method removes the inner portion and the outer portion to expose the border region of the photomask. The border region of the photomask is etched using the photoresist as a mask to form the EUV mask with a non-reflective border. The photoresist is removed from the EUV mask. The method includes forming another photoresist over a partially-fabricated integrated circuit layer and patterning the photoresist by exposure to EUV light reflected from the EUV mask to expose portions of the partially-fabricated integrated circuit layer. Portions of the partially-fabricated integrated circuit layer and the photoresist are removed.

Abstract: A method for fabricating integrated circuits includes fabricating an EUV mask by providing a photomask having a border region. A photoresist is formed over the photomask and has a border region overlying the border region of the photomask. The method exposes an inner portion and an outer portion of the photoresist border region. The method removes the inner portion and the outer portion to expose the border region of the photomask. The border region of the photomask is etched using the photoresist as a mask to form the EUV mask with a non-reflective border. The photoresist is removed from the EUV mask. The method includes forming another photoresist over a partially-fabricated integrated circuit layer and patterning the photoresist by exposure to EUV light reflected from the EUV mask to expose portions of the partially-fabricated integrated circuit layer. Portions of the partially-fabricated integrated circuit layer and the photoresist are removed.

Abstract: A first example embodiment provides a method of removing first spacers from gates and incorporating a low-k material into the ILD layer to increase device performance. A second example embodiment comprises replacing the first spacers after silicidation with low-k spacers. This serves to reduce the parasitic capacitances. Also, by implementing the low-k spacers only after silicidation, the embodiments' low-k spacers are not compromised by multiple high dose ion implantations and resist strip steps. The example embodiments can improve device performance, such as the performance of a rim oscillator.

Abstract: An example process to remove spacers from the gate of a NMOS transistor. A stress creating layer is formed over the NMOS and PMOS transistors and the substrate. In an embodiment, the spacers on gate are removed so that stress layer is closer to the channel of the device. The stress creating layer is preferably a tensile nitride layer. The stress creating layer is preferably a contact etch stop liner layer. In an embodiment, the gates, source and drain region have a silicide layer thereover before the stress creating layer is formed. The embodiment improves the performance of the NMOS transistors.

Abstract: A method for forming silicide contacts in integrated circuits (ICs) is described. A spacer pull-back etch is performed during the salicidation process to reduce the stress between the spacer and source/drain silicide contact at the spacer undercut. This prevents the propagation of surface defects into the substrate, thereby minimizing the occurrence of silicide pipe defects. The spacer pull-back etch can be performed after a first annealing step to form the silicide contacts.

Abstract: An integrated circuit system that includes: providing a substrate including a first device and a second device; configuring the first device and the second device to include a first spacer, a first liner made from a first dielectric layer, and a second spacer made from a sacrificial spacer material; forming a second dielectric layer over the integrated circuit system; forming a first device source/drain and a second device source/drain adjacent the second spacer and through the second dielectric layer; removing the second spacer without damaging the substrate; forming a third dielectric layer over the integrated circuit system before annealing; and forming a fourth dielectric layer over the integrated circuit system that promotes stress within the channel of the first device, the second device, or a combination thereof.

Abstract: A method for forming silicide contacts in integrated circuits (ICs) is described. A spacer pull-back etch is performed during the salicidation process to reduce the stress between the spacer and source/drain silicide contact at the spacer undercut. This prevents the propagation of surface defects into the substrate, thereby minimizing the occurrence of silicide pipe defects. The spacer pull-back etch can be performed after a first annealing step to form the silicide contacts.

Abstract: A method for forming silicide contacts in integrated circuits (ICs) is described. A spacer pull-back etch is performed during the salicidation process to reduce the stress between the spacer and source/drain silicide contact at the spacer undercut. This prevents the propagation of surface defects into the substrate, thereby minimizing the occurrence of silicide pipe defects. The spacer pull-back etch can be performed after a first annealing step to form the silicide contacts.

Abstract: A first example embodiment provides a method of removing first spacers from gates and incorporating a low-k material into the ILD layer to increase device performance. A second example embodiment comprises replacing the first spacers after silicidation with low-k spacers. This serves to reduce the parasitic capacitances. Also, by implementing the low-k spacers only after silicidation, the embodiments' low-k spacers are not compromised by multiple high dose ion implantations and resist strip steps. The example embodiments can improve device performance, such as the performance of a rim oscillator.

Abstract: A method for forming silicide contacts in integrated circuits (ICs) is described. A spacer pull-back etch is performed during the salicidation process to reduce the stress between the spacer and source/drain silicide contact at the spacer undercut. This prevents the propagation of surface defects into the substrate, thereby minimizing the occurrence of silicide pipe defects. The spacer pull-back etch can be performed after a first annealing step to form the silicide contacts.

Abstract: A first example embodiment provides a method of removing first spacers from gates and incorporating a low-k material into the ILD layer to increase device performance. A second example embodiment comprises replacing the first spacers after silicidation with low-k spacers. This serves to reduce the parasitic capacitances. Also, by implementing the low-k spacers only after silicidation, the embodiments' low-k spacers are not compromised by multiple high dose ion implantations and resist strip steps. The example embodiments can improve device performance, such as the performance of a rim oscillator.

Abstract: An integrated circuit system that includes: providing a substrate including a first device and a second device; configuring the first device and the second device to include a first spacer, a first liner made from a first dielectric layer, and a second spacer made from a sacrificial spacer material; forming a second dielectric layer over the integrated circuit system; forming a first device source/drain and a second device source/drain adjacent the second spacer and through the second dielectric layer; removing the second spacer without damaging the substrate; forming a third dielectric layer over the integrated circuit system before annealing; and forming a fourth dielectric layer over the integrated circuit system that promotes stress within the channel of the first device, the second device, or a combination thereof.

Abstract: An integrated circuit system that includes: providing a substrate and a material layer; measuring a parameter of the material layer; and correlating the thickness of an anti-reflective layer to the measured parameter of the material layer for critical dimension control.

Abstract: An example process to remove spacers from the gate of a NMOS transistor. A stress creating layer is formed over the NMOS and PMOS transistors and the substrate. In an embodiment, the spacers on gate are removed so that stress layer is closer to the channel of the device. The stress creating layer is preferably a tensile nitride layer. The stress creating layer is preferably a contact etch stop liner layer. In an embodiment, the gates, source and drain region have a silicide layer thereover before the stress creating layer is formed. The embodiment improves the performance of the NMOS transistors.

Abstract: A semiconductor system is provided including providing a semiconductor substrate; forming PMOS and NMOS transistors in and on the semiconductor substrate; forming a tensile strained layer on the semiconductor substrate; and relaxing the tensile strained layer around the PMOS transistor.