Abstract: A method for processing a semiconductor wafer uses non-contact electrical measurements indicative of at least one tip-to-tip short or leakage, at least one tip-to-side short or leakage, and at least one chamfer short or leakage, where such measurements are obtained from non-contact pads associated with respective tip-to-tip short, tip-to-side short, and chamfer short test areas.

Abstract: A method for processing a semiconductor wafer uses non-contact electrical measurements indicative of at least one chamfer short or leakage, at least one corner short or leakage, and at least one via open or resistance, where such measurements are obtained from non-contact pads associated with respective chamfer short, corner short, and via open test areas.

Abstract: A method for processing a semiconductor wafer uses non-contact electrical measurements indicative of at least one tip-to-tip short or leakage, at least one side-to-side short or leakage, and at least one chamfer short or leakage, where such measurements are obtained from non-contact pads associated with respective tip-to-tip short, side-to-side short, and chamfer short test areas.

Abstract: An integrated circuit, in the form of a wafer, die, or chip, includes multiple standard cell-compatible fill cells, configured to enable non-contact electrical measurements. Such fill cells include mesh pads that contain at least three conductive stripes disposed between adjacent gate stripes. Such fill cells further include geometry to enable non-contact evaluation of tip-to-side shorts and/or leakages.

Abstract: Described is a method for automatically determining proposed standard cell design conformance based upon template constraints.

Abstract: A process for making and using a semiconductor wafer includes instantiating first and second designs of experiments (DOES), each comprised of at least two fill cells. The fill cells contain structures configured to obtain in-line data via non-contact electrical measurements (“NCEM”). The first DOE contains fill cells configured to enable non-contact (NC) detection of merged-via opens, and the second DOE contains fill cells configured to enable NC detection of stitch opens. The process may further include obtaining NC measurements from the first and/or second DOE(s) and using such measurements, at least in part, to selectively perform additional processing, metrology or inspection steps on the wafer, and/or on other wafer(s) currently being manufactured.

Abstract: A capacitance measurement test vehicle comprises multiple product layers which are used to build memories except interconnect layers, and one or more customized interconnect layers to connect memory-bit-line-under-tests (MBLUTs), memory-world-line-under-tests (MWLUTs) and memory-bit-cell-under-tests (MUTs). By introducing two transistors, one PMOS and one NMOS, at two opposite sides or the same side of a bit-line or a world-line, the capacitance of the bit-line or the world-line can be measured by a parametric tester. The PMOS device is for pumping in current, and the NMOS device is for draining out the current. By applying a non-overlapping clocked signal at the PMOS and NMOS transistors, the capacitance of bit-line, word-line and bit-cell can be measured as current signal. The PMOS and NMOS transistors are selected from on-chip transistors that are already in the memory design layout.

Abstract: A process for making and using a semiconductor wafer includes instantiating first and second designs of experiments (DOES), each comprised of at least two fill cells. The fill cells contain structures configured to obtain in-line data via non-contact electrical measurements (“NCEM”). The first DOE contains fill cells configured to enable non-contact (NC) detection of via opens, and the second DOE contains fill cells configured to enable NC detection of metal island opens. The process may further include obtaining NC measurements from the first and/or second DOE(s) and using such measurements, at least in part, to selectively perform additional processing, metrology or inspection steps on the wafer, and/or on other wafer(s) currently being manufactured.

Abstract: Wafers, chips, or dies that contain fill cells with structures configured to obtain in-line data via non-contact electrical measurements (“NCEM”). Such NCEM-enabled fill cells may target/expose a variety of open-circuit, short-circuit, leakage, or excessive resistance failure modes, including GATECNT-tip-to-side-short and/or GATECNT-tip-to-side-leakage failure modes. Such wafers, chips, or dies may include Designs of Experiments (“DOEs”), comprised of multiple NCEM-enabled fill cells, of at least two types, all targeted to the same failure mode.

Abstract: An improved standard cell chip, library and/or process ensures that there is adequate spacing between TSCUT jogs and nearby gate contacts to avoid inadvertent shorts/leakages that can degrade manufacturing yield or performance.

Abstract: Improved processes for manufacturing semiconductor wafers, chips, or dies utilize in-line data obtained from non-contact electrical measurements (“NCEM”) of fill cells that contain structures configured to target/expose a variety of open-circuit, short-circuit, leakage, and/or excessive resistance failure modes. Such processes include evaluating one or more Designs of Experiments (“DOEs”), each comprised of multiple NCEM-enabled fill cells, in at least two variants, targeted to the same failure mode. Such DOEs include multiple means/steps for enabling non-contact (NC) detection of GATECNT-GATE via opens.

Abstract: Disclosed are methods for measuring capacitance in presence of leakage in integrated circuits. In particular, it teaches a method of measuring leaky capacitors using charge based capacitance measurement (CBCM) technique taking into account parasitic resistance. Fast and accurate measurement of capacitances allows the estimation of a number of technology parameters like: gate-dielectric thickness, gate critical dimension, trench depth in a damascene metallization process, height of a fin in a Fin FET device etc.

Abstract: An integrated circuit, in the form of a wafer, die, or chip, includes multiple standard cell-compatible fill cells, configured to enable non-contact electrical measurements. Such fill cells include mesh pads that contain at least three conductive stripes disposed between adjacent gate stripes. Such fill cells further include geometry to enable non-contact evaluation of side-to-side shorts and/or leakages.

Abstract: A process for making an integrated circuit, either in the form of a wafer, die, or chip, includes instantiating multiple standard cell-compatible fill cells, configured to enable non-contact electrical measurements. Such instantiated fill cells include mesh pads that contain at least three conductive stripes disposed between adjacent gate stripes. Such instantiated fill cells further include geometry to enable non-contact evaluation of Tip-to-Side shorts and/or leakages.

Abstract: A process for making and using a semiconductor wafer includes instantiating first and second designs of experiments (DOES), each comprised of at least two fill cells. The fill cells contain structures configured to obtain in-line data via non-contact electrical measurements (“NCEM”). The first DOE contains fill cells configured to enable non-contact (NC) detection of tip-to-side shorts, and the second DOE contains fill cells configured to enable NC detection of chamfer shorts. The process may further include obtaining NC measurements from the first and/or second DOE(s) and using such measurements, at least in part, to selectively perform additional processing, metrology or inspection steps on the wafer, and/or on other wafer(s) currently being manufactured.

Abstract: A process for making and using a semiconductor wafer includes instantiating first and second designs of experiments (DOEs), each comprised of at least two fill cells. The fill cells contain structures configured to obtain in-line data via non-contact electrical measurements (“NCEM”). The first DOE contains fill cells configured to enable non-contact (NC) detection of side-to-side shorts, and the second DOE contains fill cells configured to enable NC detection of chamfer shorts. The process may further include obtaining NC measurements from the first and/or second DOE(s) and using such measurements, at least in part, to selectively perform additional processing, metrology or inspection steps on the wafer, and/or on other wafer(s) currently being manufactured.

Abstract: An integrated circuit, in the form of a wafer, die, or chip, includes multiple standard cell-compatible fill cells, configured to enable non-contact electrical measurements. Such fill cells include mesh pads that contain at least three conductive stripes disposed between adjacent gate stripes. Such fill cells further include geometry to enable non-contact evaluation of snake opens and/or resistances.

Abstract: An integrated circuit, in the form of a wafer, die, or chip, includes multiple standard cell-compatible fill cells, configured to enable non-contact electrical measurements. Such fill cells include mesh pads that contain at least three conductive stripes disposed between adjacent gate stripes. Such fill cells further include geometry to enable non-contact evaluation of diagonal shorts and/or leakages.

Abstract: An integrated circuit, in the form of a wafer, die, or chip, includes multiple standard cell-compatible fill cells, configured to enable non-contact electrical measurements. Such fill cells include mesh pads that contain at least three conductive stripes disposed between adjacent gate stripes. Such fill cells further include geometry to enable non-contact evaluation of corner shorts and/or leakages.

Abstract: Wafers, chips, or dies that contain fill cells with structures configured to obtain in-line data via non-contact electrical measurements (“NCEM”). Such NCEM-enabled fill cells may target/expose a variety of open-circuit, short-circuit, leakage, or excessive resistance failure modes, and may include NCEM pads that comprise a mesh of GATECNT and AACNT stripes. Such wafers, chips, or dies may include Designs of Experiments (“DOEs”), comprised of multiple NCEM-enabled fill cells, in at least two variants, all targeted to the same failure mode(s).