A practical method of measuring the contact resistance of a phosphorus-doped poly-Si plug formed on a lightly phosphorus-doped diffusion region in DRAM memory cells is described. Contact resistance was obtained electrically, using ordinary contact-chain test structures, by changing the measurement of the substrate bias. This separated the bias-dependent resistance of the lightly doped diffusion layer from the total resistance. The method was used experimentally to evaluate the feasibility of forming low-resistance contacts down to a diameter of 130 nm for giga-bit DRAMs. Electrical measurement showed that reducing the interface resistance between the poly-Si plug and the lightly doped diffusion layer was effective for forming low-resistance contacts, though a specific interface layer could not be detected by TEM observation.

The concentration of the electric field at the edge of the electrode has been simulated in several types of flat DRAM cell capacitors with high permittivity dielectrics. The results indicated that the permittivity of the material surrounding the edge of the electrode as well as the geometrical structure affected the concentration of the electric field. The electric field strength was minimized and most evenly distributed by utilizing the structure in which the sidewall of the capacitor dielectric was terminated at the edge of the electrode by a low-dielectric constant insulator. High-precision fabrication of the capacitor's profile is required for the minimization and uniformity of the electric field.