290 7.6 High-Throughput Techniques
Following the treatment with an appropriate photoresist developer leaves a surface pattern
consisting of some regions of exposed substrate, where, in some of the regions, the photo
resist still remains. The exposed regions are accessible to further chemical etching treatment,
but regions masked by the remaining photoresist are not. Chemical etching treatment thus
results in etched pattern onto the substrate itself. Also, at this stage, deposition or growth
onto the patterned substrate can be performed, of one or more thin layers or additional
material, for example, to generate electrically conducting, or insulating, regions of the
patterned surface.
This can be achieved using a range of techniques including thermal oxidation and chem
ical vapor deposition, physical vapor deposition methods such as sputtering and evaporative
deposition, and epitaxy methods (which deposit crystalline layers onto the substrate sur
face) (Figure 7.4b). Evaporative deposition is commonly used for controlled coating of a sub
strate in one or more thin metallic layers. This is typically achieved by placing the substrate
in a high vacuum chamber (a common vacuum chamber used is a Knudsen cell) and then
by winding solid metallic wire (e.g., gold, nickel, chromium are the common metals used)
around a tungsten filament. The tungsten filament is then electrically heated to vaporize
the metal wire, which solidifies on contact with the substrate surface. The method is essen
tially the same as that used for positive shadowing in electron microscopy (see Chapter 5).
Following any additional deposition, any remaining photoresist can be removed using spe
cific organic solvent treatment to leave a complex patterned surface consisting of etches and
deposition areas.
Sputtering is an alternative to vapor deposition for coating a substrate in a thin layer of
metal. Sputter deposition involves ejecting material from a metal target that is a source onto
the surface of the substrate to be coated. Typically, this involves gas plasma of an inert gas
such as argon. Positive argon ions, Ar+, are confined and accelerated onto the target using
magnetic fields in a magnetron device to bombard the metal sample to generate ejected metal
atoms of several tens of keV of energy. These can then impact and bind to the substrate sur
face as well as cause some resputtering of metal atoms previously bound to the surface.
Sputter deposition is largely complementary to evaporative deposition. One important
advantage of sputtering is that it can be applied to metals with very high vaporization
temperatures that may not be easy to achieve with typical evaporative deposition devices.
Also, the greater speed of ejected metal atoms compared to the more passive diffusive speed
from evaporative deposition results in greater adhesion to substrate surfaces in general. The
principal disadvantage of sputtering over evaporative deposition is that sputtering does not
generate a distinct metallic shadow around topographic features in the same way that evap
orative deposition does because of the extra energy of the ejected metal atoms, resulting in
a diffusive motion around the edges of these surface features; this can make the process of
lift-off more difficult.
Microfabrication methods have been used in conjunction with biological conjugation
tools (see the previous section of this chapter) to biochemically functionalize surfaces, for
example, to generate platforms for adhesion of single DNA molecules to form DNA curtains
(see Chapter 6). Also, by combining controlled metallic deposition on a microfabricated sur
face with specific biochemical functionalization, it is possible to generate smart bioelectronics
circuitry. Smart surface structures can also utilize molecular self-assembly techniques, such
as DNA origami (discussed in Chapter 9).
Important recent advances have been made in the area of nanophotonics using
microfabrication and nanofabrication technologies. Many silicon-based substrates, such as
silicon dioxide “glass,” have low optical absorption and a reasonably high refractive index of
~1.5 in the visible light spectrum range, implying that they are optically transparent and can
also act as photonic waveguides for visible light. A key benefit here in terms of biophysical
applications is that laser excitation light for fluorescence microscopy can be guided through
a silicon-based microfabricated device across significant distances; for example, if coupled to
an optic fiber delivery system to extend to waveguide distance, this is potentially only limited
by the optical fiber repeater distance of several tens of kilometers.
This potentially circumvents the need to have objective lens standard optical microscopy-
based delivery and capture methods for light and so facilitates miniaturization of devices that