A test structure to separately analyze the location where the hot-carrier-induced CMOSFET reliability is determined around the center or the isolation-edge along the channel-width was proposed and fabricated. The test structure has four kinds of MOSFETs; [A] and [D] MOSFETs with a short and a long channel-length all over the channel width, respectively, [B] MOSFET with the short and the long channel-length around the center and the both isolation-edges, respectively, and [C] MOSFET with the channel-length regions vice versa to the [B] MOSFET. The time dependent changes of the threshold voltages VT, the saturation currents IS, the linear currents IL and the maximum transconductances β up to 50,000 s were measured. All data for the wide channel-width MOSFETs were almost categorized into three; [A], [B]/[C] and [D]. The [B]/[C] data were well estimated from simple theoretical discussions by the combination of [A] and [D] data, which mean that the reliabilities are nearly the same around the center or the isolation-edge for the CMOSFETs.

A test structure to separately measure sheet resistances of highly-doped-drain (HDD) and lightly-doped-drain (LDD) in LDD-type CMOSFETs with various gate spaces S having sub-100 nm sidewalls was proposed. From the reciprocal of source/drain-resistance R-1 versus S characteristics, the sheet resistance ρH of the high-conductive-region (HCR) corresponding to HDD and the approximate width WLC of the low-conductive-region (LCR) corresponding to LDD could be estimated. Both of ρH and WLC for p- and n-MOS devices were scarcely dependent on the gate voltage. The sidewall-width difference of 40 nm could be sufficiently detected by using the test structure with the S pitch of about 60 nm. The R-1 versus S characteristics showed the unstable resistance variations in the narrow S region less than 0.3 µm, which corresponded to the minimum S for the process used for the test device fabrication and suggested that various micro-loading effects seriously affected on the characteristics.