human body [31]. Other examples of implantable actuator systems are drug dosage devices
for hormones such as insulin. The first systems have been used as semi-implants in the form
of an insulin pump for the treatment of type I diabetes [13], but fully implantable systems
are also under development.
21.3 Biocompatibility
The insertion of microelectronic systems into the body of humans or other mammals is a
challenging task because the underlying material systems have emerged from different
development processes and are largely incompatible with each other. For example, the
tertiary and quaternary structure adopted for the function of proteins is generally de
stroyed when they come into contact with engineered surfaces [32,33]. On the other hand,
the thin-film stacks from which microelectronic chips are constructed tend to corrode and
become defunctionalized when they are in contact with electrolyte solutions for extended
periods [27,34–36].
In particular, the metallic conductive electrode layers made of Al, Ti, W, and CoSi2 as
used in CMOS chips degrade within a short period [34,35]. Figure 21.4 shows the cor
rosion of a meander-shaped conductor track made of Al:Cu on SiO2, which was stored
for a few days in saline. Of all the materials used in CMOS technologies, only the ceramic,
yet electrically highly conductive titanium nitride TiN is sufficiently stable to withstand
the harsh environmental conditions in body fluids over extended periods [34–36]. Depth-
resolved XPS studies have shown that the effect is associated with a 1–2 nm thin oxidized
surface, i.e., the presence of an ultrathin TiO2 layer [34]. Accordingly, thin TiN films are
well suited for coupling voltages into electrolyte solutions. However, currents can only
be introduced as dielectric displacement currents and not in the form of charges crossing
the interface because the surface TiO2 coating acts as an insulator. This explanatory
model correlates well with other observations such as (i) the very low charge transfers –
compared to gold electrodes – observed for TiN layers as working electrodes in an
electrochemical cell [34] or (ii) the use of 30 nm thin TiO2 layers for hermetic en
capsulation of implantable needles for voltage measurement in neuronal tissues [37].
However, not only electrically conductive electrode surfaces but also structural mate
rials such as the SiN-based passivation layer are corroded in body fluid. In the backend
FIGURE 21.4
Optical micrographs of metallic meander structures of TiN/Al:Cu/TiN multilayer stack. Both figures show the
same chip section, (top) initial (bottom) after five days in 0.9% saline.
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