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Bottoms-up ELD of Cobalt Plugs

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As reported in more detail at Solid State Technology, during the IEEE IITC now happening in Grenoble, imec and Lam showed a new Electroless Deposition (ELD) cobalt (Co) process that is claimed to provide void-free bottoms-up pre-filling of vias and contacts. The unit-process is intended to be integrated into flows to produce scaled interconnects for logic and DRAM ICs at the 7nm node and below. Co-incidentally at IITC this year, imec and Lam also presented on a new ELD copper (Cu) process for micron-plus-scale through-silicon vias (TSV).

The bulk resistivities of metals commonly used in IC fabrication are as follows (E-8 Ω⋅m):
Cu – 1.70,
Al – 2.74,
W – 5.3, and
Co – 5.8.
Of course, the above values for bulk materials assume minimal influence of grain sizes and boundary layers. However, in scaled on-chip interconnect structures using in today’s advanced ICs, the resistivity is dominated by grain-boundaries and interfacial materials. Consequently, the resistivity of vias in 7nm node and beyond interconnects may be similar for Cu and Co depending upon the grain-sizes and barrier layers.

The melting temperatures of these metals are as follows (°C):
Al – 660,
Cu – 1084,
Co – 1495, and
W – 3400.
With higher melting temperature compared to Cu, Co contacts/plugs would provide some of the thermal stability of W to allow for easier integration of transistors and interconnects. Seemingly, the main reason to use Co instead of W is that the latter requires CVD processing that intrinsically does not allow for bottom-up deposition.

—E.K.

Figure 1: Leti’s 300mm diameter silicon wafer fabrication line on the MINATEC campus in Grenoble, France. In the foreground is space for a new fab intended for work on silicon-photonics. (Source: Ed Korczynski)

Figure 1: Leti’s 300mm diameter silicon wafer fabrication line on the MINATEC campus in Grenoble, France. In the foreground is space for a new fab intended for work on silicon-photonics. (Source: Ed Korczynski)

Now I know how wafers feel when moving through a fab. Leti in Grenoble, France does so much technology integration that in 2010 it opened a custom-developed people-mover to integrate cleanrooms (“Salles Blanches” in French) it calls a Liaison Blanc-Blanc (LBB) so workers can remain in bunny-suits while moving batches of wafers between buildings. I got to ride the LBB from the 300mm diameter wafer silicon CMOS and 200mm diameter wafer MEMS fabs (Fig.1) along the cement monorail to the more specialized fab spaces for industrial partners and for nanoelectronics start-ups. This was my first time experiencing this world-exclusive ISO 6 (“Class 1000”) mobile cleanroom, and it very nicely moves people in 3 minutes between cleanroom buildings that would otherwise take 30 minutes of de-gowning and walking and re-gowning. In the foreground of Fig.1 is space for a new fab intended for silicon-photonics R&D and pilot fabrication.

Figure 2: Leti’s “Liaison Blanc-Blanc” (LBB) ISO 6 mobile cleanroom connects buildings on the MINATAC campus with elevator-like automation along a cement monorail. (Source: Ed Korczynski)

Figure 2: Leti’s “Liaison Blanc-Blanc” (LBB) ISO 6 mobile cleanroom connects buildings on the MINATAC campus with elevator-like automation along a cement monorail. (Source: Ed Korczynski)

Fig.2 shows the LBB as it passes a Linde gas tower in front of spectacular alpine scenery on the way to Leti’s specialized and start-up fab building. One of Leti’s great strengths is that it does more than just lab-scale R&D, but has invested in all of the tools and facilities to be able to do pilot manufacturing of nanoscale devices. Didier Louis, Leti international communications manager and gracious tour host through the cleanrooms, explained that when working with new materials a pragmatic approach is needed; for example, color coding for wafer transport carriers informs if there is no copper, copper encased by other materials, or exposed copper on wafers therein.
—E.K.