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  • IITC - Imec Presents Copper, Cobalt and Ruthenium Interconnect Results

    The IEEE Interconnect Technology Conference (IITC): Advanced Metallization Conference was held June 4th through 7th in Santa Clara. Imec presented multiple papers on comparing copper, cobalt and ruthenium interconnect. One paper in particular caught my eye: Marleen H. van der Veen, # N. Heylen, O. Varela Pedreira, S. Decoster, V. Vega Gonzalez, N. Jourdan, H. Struyf, K. Croes, C. J. Wilson, and Zs. Tőkei, "Damascene benchmark of Ru, Co and Cu in scaled dimensions" and I had the chance to not only review the paper but also to interview one of the papers authors, Zsolt Tokeis.

    Background
    The resistance of an interconnect line depends on the line length, cross sectional area and the resistivity of the material, see figure 1.
    CES 2013 Trip Reports (Win an iPad Mini!)-slide1.jpg


    Figure 1. Line Resistance and Material Properties.

    On the left side of figure 1 is the formula to determine the resistance of an interconnect line. On the right side of the figure is the bulk resistivity and electron mean free path for selected materials. From the table it can be seen that copper has the lowest bulk resistivity of any of the listed materials, however as the cross-sectional area of an interconnect lines scales down resistivity increases due to scattering. The longer the electron mean free path is in a material the more the resistivity increases as the area is reduced. Copper has a long electron mean free path and is strongly affected by cross sectional area.

    The other issue with copper is a barrier layer is required to prevent the copper from contaminating the rest of the structure. Barrier layers are made of materials such as Tantalum Nitride with very high resistivity and the barriers don't scale down in thickness as the cross sectional area scales down, see figure 2.

    CES 2013 Trip Reports (Win an iPad Mini!)-slide2.jpg


    Figure 2. Copper Scaling.

    Currently copper barriers are around 2nm to 4nm in thickness with 2nm a lower limit. From the figure you can see that scaling from a 14nm node to a 10nm node reduces the copper cross sectional area to 0.33x for a 4nm barrier and 0.48x for a 2nm barrier.

    The problems with increasing resistivity as linewidths shrink and barrier resistance open the door for other materials to displace copper at small linewidths if the resistivity doesn't increase as much with cross sectional area and thinner or no barrier can implementations are possible.

    Cobalt and Ruthenium are the two leading materials to replace copper at small dimensions.

    Imec Line Resistance Results
    Imec created 15nm trench openings on a 44nm pitch and then shrunk the trench width by depositing a conformal SiO2 layer using Atomic Layer Deposition (ALD). The resistance of lines created by filling the trenches with various were then measured. Figure 3 is the measured resistance of the lines.
    CES 2013 Trip Reports (Win an iPad Mini!)-imec-resistance.jpg


    Figure 3. Line Resistance Versus Conductor Area
    (figure 3 from the imec paper).

    Figure 3 from the papers looks at copper with a 2nm barrier (the minimum achievable) versus cobalt and ruthenium with no barriers and 0.3nm adhesion layers. Cobalt and Ruthenium migrate less than copper and can be used without barriers (more on this later).

    Plot (a) in the figure is the line resistance versus the cross-sectional area of the conductor material with the cross-sectional area determined electrically and excluding the barrier. From the figure you can see that the resistance goes up for all materials as the cross-sectional area is reduced with copper always having the lowest resistance. Plot (b) in the figure is the resistance of the overall line including barriers and shows that at around 300nm2 conductor cross-sectional area cobalt and ruthenium are superior to copper.

    For a typical aspect ratio this is equivalent to an approximately 12nm linewidth. For advanced nodes there is a trend for critical interconnect layers to have wide lines and narrow spaces between the lines to minimize resistance. A 12nm line would be typical from something like a 16nm pitch, smaller than is likely to be required any time soon.

    Via Resistance
    For the lower level interconnects lines are relatively short and vias are common. Via resistance can therefore become a very important factor in interconnect resistance and barriers in vias contribute a lot of resistance. Figure 4 illustrates the via resistance versus critical dimension (CD).

    CES 2013 Trip Reports (Win an iPad Mini!)-imec-vias.jpg

    Figure 4. Via Resistance Versus CD
    (figure 5 in the imec paper).

    Figure 4 compares ruthenium with no barrier, cobalt with no barrier, cobalt with a 1nm titanium nitride barrier and copper with a 1nm ruthenium barrier and 1.5nm tantalum nitride barrier. At all CDs ruthenium and cobalt outperform copper. It has been found that barrier-less cobalt is only usable with dense inter level dielectric layers so some barrier may be required depending on the ILD. Ruthenium does not require a barrier at all.

    The lower resistance of cobalt and ruthenium vias shifts the pitch at which teh material out perform copper. It is somewhat design dependent but at a 40nm pitch copper is the best, by the time you scale down to 32nm pitch cobalt and ruthenium perform better.

    Currently cobalt has been implemented by some companies for contacts at 7nm and Intel is using cobalt interconnect for soem levels for their 10nm (roughly equivalent to foundry 7nm) technology. Ruthenium has the best via and interconnect resistance at small dimension but is very difficult to process.

    Electromigration
    Even with the relatively small currents that exist in state-of-the art ICs, the small cross-sectional area of the conductors leads to high current density. Momentum transfer from electrons to the conductor atoms can cause the conductor atoms to migrate and eventually create breaks in the conductor. This is referred to as electromigration and is a serious issue particularly in higher performance designs. The electromigration resistance of a material can be characterized by the activation energy of the material for electromigration to occur where the activation energy is an exponential factor. The electromigration activation energy is proportional to the materials melting point and cobalt and particularly ruthenium shows greatly improved electromigration resistance compared to copper.

    Discussion

    Taking line resistance, via resistance and electromigration into account imec draws the line at around a 40nm pitch for cobalt or ruthenium to outperform copper.

    Imec is working on a barrier-less cobalt solution with dense low-k iILD materials, electromigration performance is good but without a barrier cobalt does intermix with copper where the two materials come into contact at high interconnect levels.

    Ruthenium doesn't need a barrier but CMP of ruthenium is still problematic.