M. Angyal scite author profile

IntroductionA high performance 0.20pm logic technology has been developed with six levels of planarized copper interconnects. 0.15pm transistors (Lg,,,=0.15+0.04pm) are optimized for 1.8V operation to provide high performance with low power-delay products and excellent reliability. Copper has been integrated into the back-end to provide low resistance interconnects. Critical layer pitches for the technology are summarized in Table 1 and enable fabrication of 7.6pm2 6T SRAM cells.Isolation and Transistors CMP planarized shallow trenches with good electrical isolation down to n+/p+ spacings of 0.5pm were fabricated (Fig. 1). Dual gate 0.15pm transistors with 35A physical gate oxides (accumulation t,,=39A measured at Vg=+l .SV) were formed using super steep retrograde channels, shallow extensions and halos, relatively deep source/drain regions and 1 OOnm nitride spacers. CoSi, was selectively formed on the polysilicon gates and source/drain regions with a nominal sheet resistance of 9Wsq. Rapid thermal processing was utilized as much as possible throughout the flow to minimize transient enhanced dopant diffusion.Fig. 2 shows a typical SEM cross-section of a NMOS transistor with a gate length of 0.15pm. Well delineated shallow S/D extensions and the deeper S/D junctions are clearly observed. The saturation drive currents for nominal gate length NMOS and PMOS devices are shown in Fig. 3 . The nominal drive currents are 630pNpm for NMOS and 230pA/ym for PMOS at 1.8V. The off-state leakage currents of these devices are well below the worst case leakage specification of 2nA/pm. The drain induced barrier lowering (DIBL) measured on NMOS and PMOS devices is plotted as a function of Leff in Fig. 4. Good short channel characteristics are maintained down to effective channel lengths of O.1ym. The Vt roll-off for N and P devices in the linear and saturation regions are shown in Fig. 5. The Vt's are 0.44V and -0.46V for Nch and Pch respectively, at a gate length of 0.15pm and the associated subthreshold slopes are less than 90mv/dec. The use of nitrided gate oxides was investigated due to their superior hot carrier reliability. Fig. 6 compares the degradation under hot carrier stress of nitrided oxides to thermal oxides and highlights the improved reliability of NO-annealed oxides. Peak Gms comparable to those from thermal oxides were obtained (Fig. 7). A further advantage afforded by nitrided gate dielectrics is its superior boron blocking properties, Increasing the poly silicon doping in the P+ gate to reduce poly depletion resulted in only a 88mV Vt shift in nitrided oxides (Fig. 8) compared to a 300mV Vt shift in thermal oxides. A significant reduction in the inversion to, is achieved with the higher gate doping, resulting in improved device characteristics. NMOS transistor design focused on minimizing defect enhanced dopant re-distribution such as TED. To this end, the effect of different source/drain implant energies on NMOS transistor performance is shown in Fig. 9. The lower energy implant results in a significantl...

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Electromigration in Cu(Al) and Cu(Mn) damascene lines

Hu¹,

Ohm²,

Gignac³

et al. 2012

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The effects of impurities, Mn or Al, on interface and grain boundary electromigration (EM) in Cu damascene lines were investigated. The addition of Mn or Al solute caused a reduction in diffusivity at the Cu/dielectric cap interface and the EM activation energies for both Cu-alloys were found to increase by about 0.2 eV as compared to pure Cu. Mn mitigated and Al enhanced Cu grain boundary diffusion; however, no significant mitigation in Cu grain boundary diffusion was observed in low Mn concentration samples. The activation energies for Cu grain boundary diffusion were found to be 0.74 ± 0.05 eV and 0.77 ± 0.05 eV for 1.5 μm wide polycrystalline lines with pure Cu and Cu (0.5 at. % Mn) seeds, respectively. The effective charge number in Cu grain boundaries Z*GB was estimated from drift velocity and was found to be about −0.4. A significant enhancement in EM lifetimes for Cu(Al) or low Mn concentration bamboo-polycrystalline and near-bamboo grain structures was observed but not for polycrystalline-only alloy lines. These results indicated that the existence of bamboo grains in bamboo-polycrystalline lines played a critical role in slowing down the EM-induced void growth rate. The bamboo grains act as Cu diffusion blocking boundaries for grain boundary mass flow, thus generating a mechanical stress-induced back flow counterbalancing the EM force, which is the equality known as the “Blech short length effect.”

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Electromigration-resistance enhancement with CoWP or CuMn for advanced Cu interconnects

Christiansen¹,

Li²,

Angyal

et al. 2011

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High performance 65 nm SOI technology with dual stress liner and low capacitance SRAM cell

Leobandung

Nayakama²,

Mocuta

et al.

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M. Angyal

Electroless copper deposition for ULSI

A high performance 1.8 V, 0.20 μm CMOS technology with copper metallization

Electromigration in Cu(Al) and Cu(Mn) damascene lines

Electromigration-resistance enhancement with CoWP or CuMn for advanced Cu interconnects

High performance 65 nm SOI technology with dual stress liner and low capacitance SRAM cell

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