Process for making and using a semiconductor wafer containing first and second DOEs of standard cell compatible, NCEM-enabled fill cells, with the first DOE including tip-to-tip short configured fill cells, and the second DOE including chamfer short configured fill cells
First Claim
1. A process for making a semiconductor wafer that includes at least a source/drain (AA) layer, a source/drain contact (AACNT) layer, a source/drain silicide (TS) layer, a gate (GATE) layer, and a gate contact (GATECNT) layer, the process comprising at least:
- (i) creating a first design of experiments (DOE) by instantiating, on the wafer, at least first and second non-contact electrical measurement (NCEM)-enabled fill cells in a standard cell form, with first and second supply rails that extend horizontally across the cells and uniformly spaced GATE stripes that extend vertically across the cells, said creating further including instantiating, on the wafer, test gap patterning that comprises first and second features, arranged in a tip-to-tip short configuration, with the first feature electrically connected to an NCEM pad and the second feature electrically connected to a permanent or virtual ground, thereby enabling detection of an unintended short or leakage between the first and second features using a non-contact (NC) measurement at the NCEM pad, said creating further including providing at least one patterning difference between the first and second NCEM-enabled fill cells that results in a different probability of detecting shorts or leakages between the first and second features of the first NCEM-enabled fill cell and the first and second features of the second NCEM-enabled fill cell; and
,(ii) creating a second DOE by instantiating, on the wafer, at least first and second NCEM-enabled fill cells in a standard cell form, with first and second supply rails that extend horizontally across the cells and uniformly spaced GATE stripes that extend vertically across the cells, said creating further including instantiating, on the wafer, test gap patterning that comprises first and second features, arranged in a chamfer short configuration, with the first feature electrically connected to an NCEM pad and the second feature electrically connected to a permanent or virtual ground, thereby enabling detection of an unintended short or leakage between the first and second features using a NC measurement at the NCEM pad, said creating further including providing at least one patterning difference between the first and second NCEM-enabled fill cells that results in a different probability of detecting shorts or leakages between the first and second features of the first NCEM-enabled fill cell and the first and second features of the second NCEM-enabled fill cell;
wherein creating the first and second DOEs further comprises instantiating all of the NCEM-enabled fill cells in the first and second DOEs in a compatible standard cell form, with identical spacing between the first and second supply rails and identical spacing between adjacent GATE stripes.
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Accused Products
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-tip 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.
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Citations
20 Claims
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1. A process for making a semiconductor wafer that includes at least a source/drain (AA) layer, a source/drain contact (AACNT) layer, a source/drain silicide (TS) layer, a gate (GATE) layer, and a gate contact (GATECNT) layer, the process comprising at least:
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(i) creating a first design of experiments (DOE) by instantiating, on the wafer, at least first and second non-contact electrical measurement (NCEM)-enabled fill cells in a standard cell form, with first and second supply rails that extend horizontally across the cells and uniformly spaced GATE stripes that extend vertically across the cells, said creating further including instantiating, on the wafer, test gap patterning that comprises first and second features, arranged in a tip-to-tip short configuration, with the first feature electrically connected to an NCEM pad and the second feature electrically connected to a permanent or virtual ground, thereby enabling detection of an unintended short or leakage between the first and second features using a non-contact (NC) measurement at the NCEM pad, said creating further including providing at least one patterning difference between the first and second NCEM-enabled fill cells that results in a different probability of detecting shorts or leakages between the first and second features of the first NCEM-enabled fill cell and the first and second features of the second NCEM-enabled fill cell; and
,(ii) creating a second DOE by instantiating, on the wafer, at least first and second NCEM-enabled fill cells in a standard cell form, with first and second supply rails that extend horizontally across the cells and uniformly spaced GATE stripes that extend vertically across the cells, said creating further including instantiating, on the wafer, test gap patterning that comprises first and second features, arranged in a chamfer short configuration, with the first feature electrically connected to an NCEM pad and the second feature electrically connected to a permanent or virtual ground, thereby enabling detection of an unintended short or leakage between the first and second features using a NC measurement at the NCEM pad, said creating further including providing at least one patterning difference between the first and second NCEM-enabled fill cells that results in a different probability of detecting shorts or leakages between the first and second features of the first NCEM-enabled fill cell and the first and second features of the second NCEM-enabled fill cell; wherein creating the first and second DOEs further comprises instantiating all of the NCEM-enabled fill cells in the first and second DOEs in a compatible standard cell form, with identical spacing between the first and second supply rails and identical spacing between adjacent GATE stripes. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20)
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Specification