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COMMERCIAL MICRO MANUFACTURINGINTERNATIONAL
THE MAGAZINEFOR MICRO,
HIGH-PRECISION ANDMEMS MANUFACTURERS
1018
in this issuePRODUCTS INSPIRED BY NATURECO LASERSCARRIER WAFERS
COMS 2018 REVIEW
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articlea
CARSTEN WESSELKAMP, SALES MANAGER, AND MARKUS WAGNER, MARKETING
MANAGER, PLAN OPTIK
The carrier wafer— a useful and necessary tool for
MEMS and sensor packaging
MEMS and sensor packaging processes can require the handling and
processing of ultra-thin semiconductor wafers. Various thin wafer
handling systems that require a special handling tool such as a
carrier wafer (or support wafer) are already established in the
market. By temporarily bonding a device wafer to a carrier wafer,
it can be safely handled and processed. Depending on the temporary
bonding and de-bonding techniques, there are di� erent requirements
for carrier wafers. This article details the requirements for
carrier wafers as a necessary handling tool for 3D wafer level
packaging technologies.
Introduction
There is ongoing wafer thickness reduction in the MEMS and
semiconductor industry. This is because of market demand for
smaller devices that a� ord an increased number of functionalities
at reduced cost; and for this, smaller package sizes need to be
realised. It is mainly consumer applications that are responsible
for this trend, but the demand for smaller package sizes is also
attributable to technical advantages, for example better electrical
performance or improved thermal management.
Smaller package sizes require extremely thin substrates to build
up devices. Those thin and ultra-thin substrates also enable 3D
packaging of sensors such as complementary
metal-oxide-semiconductor (CMOS) image sensors and others.
Producing thin wafers in high quantities puts challenging
requirements on handling and processing tools.
Due to their low thickness, thin wafers are vulnerable to stress
and breakage. Warping of the wafers during handling and processing
causes a high yield loss or can even make it impossible to handle
the wafers any more. This means that a thin wafer handling
technology with a high degree of fl exibility on wafer and
substrate sizes is needed. Carrier wafers need to have certain
properties, such as: mechanical robustness; chemical and
high-temperature resistance; incredibly low tolerances (down to 1
μm thickness variation); and thermal expansion adjusted to the used
material, for example, gallium arsenide (GaAs), Indium phosphide
(InP), silicon (Si) or silicon carbide (SiC). Furthermore, handling
tools sometimes need to be suitable for materials such as GaAs and
Si, or even CMOS compatible.
High-end carrier wafers made of glass, quartz or silicon can
meet the aforementioned requirements. Glass and quartz are
excellent materials for carrier wafers because of their thermal
stability and resistance against acids and other chemicals. Bonding
to and de-bonding from glass and quartz carrier wafers can be
monitored since they are transparent. Furthermore, glass carrier
wafers can be cleaned
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commercial micro manufacturing international Vol 11 No. 6 35
article a
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and re-used, thus contributing to cost reduction and
environmental protection.
Thin wafer handling
In thin wafer handling processes, the device wafer is
temporarily bonded to a rigid carrier wafer of high accuracy using
a polymer-based adhesive. The general process fl ow for temporary
bonding is shown in fi gure 1. After handling and processing the
device wafer using standard semiconductor process tools, the
release (debonding) is carried out by way of various
techniques, namely chemicals dissolving the adhesive, heat
decreasing the viscosity of the adhesive or laser reducing the
adhesive force.
Debonding methods—suitable carriers for di� erent
applications
In temporary wafer bonding processes, the carrier wafer needs to
be removed from the device wafer at the end of processing.
Depending on the device characteristics and the process used, there
are di� erent specifi cation requirements for carrier
⊲ Figure 1:General process flow of temporary wafer bonding.
⊲
mailto:[email protected]
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36
articlea
⊲ Figure 2:Laser release debonding. ⊲
⊲ Figure 3:Chemical release
debonding. ⊲
⊲ Figure 4:Thermal debonding.⊲
Carrier wafer with through holes for chemical debonding.
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commercial micro manufacturing international Vol 11 No. 6 37
article a
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wafers. Di� erent types of carrier wafers with special
properties for common debonding processes are explained below.
Carrier wafers for laser release
In laser debonding, the adhesive strength is reduced by exposing
it to laser light (fi gure 2). Debonding methods can be carried out
at room temperature.
For laser debonding processes, highly transparent carrier wafers
that transmit the relevant laser wavelength are needed. Double-side
polished glass or quartz carrier wafers have excellent surface
quality and thus meet the requirements of a laser debonding
process. After laser exposure, the device wafer can be detached
from the carrier wafer. Finally, the carrier wafer needs to be
cleaned and can then be re-used several times. The laser debonding
method is mainly used in the fan-out wafer-level packaging and
advanced packaging processes.
Carrier wafers for chemical release
Here, the de-bonding is caused by chemicals that dissolve the
adhesive after processing (including thinning) of the device wafer
(fi gure 3). The carrier wafer is perforated to enable the solvent
to pass through it and come into contact with the adhesive. Such
carrier wafers can be produced by combining a blank glass carrier
with the latest patterning technologies and tight tolerances. To be
able to distribute the chemistry as fast as possible, extremely
small holes with a high density are needed. More than 150,000
through holes of equal size can be created, which a� ords smooth
and safe debonding whilst the carrier wafer withstands mechanical
infl uences.
Carrier wafers for chemical release are available at a total
thickness variation (TTV) as low as 1 micron and in many coe� cient
of linear thermal expansion (CTE) adapted materials. These carrier
wafers can be re-used up to 50 times.
Carrier wafers for thermal release
Thermoplastic adhesives are used for bonding the device wafer or
single chips to the carrier wafer. These adhesives decrease in
viscosity at higher temperatures (i.e. from 100˚C), so that having
undergone a heating process, the device wafer can be sheared from
the carrier wafer (fi gure 4). For this, imperforated carrier
wafers or carrier wafers with recessed pockets are needed.
mailto:[email protected]:[email protected]://www.spt.net/cim
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38
articlea
⊲ Reiter and a mechanical engineering company have co-developed
an
assembly robot that can detect and precisely place contact pins
despite
their minute dimensions. ⊲
Adapter carrier wafers for exceptional fl exibility
The semiconductor and MEMS industry is producing wafers with an
increasing variety of diameters. However, the processing equipment
required for di� erent wafer diameters or substrate dimensions is
not a� ordable for all companies. Adapter carrier wafers feature
pockets to hold wafers with smaller diameters or substrates of
smaller dimensions and carry them through the process (fi gure 5).
This allows
for the handling and processing of a variety of di� erent wafer
and substrate sizes on existing equipment.
Adapter carrier wafers are either surface processed glass or
silicon wafers with patterned pocket(s) or silicon wafers
permanently bonded to borosilicate glass rings that have been
patterned according to the dimensions of the substrate. The
so-formed pockets on the wafer with required outer diameter enable
processing of smaller wafers and
Adapter carrier wafers are either surface processed glass or
silicon wafers with patterned pocket(s) or silicon wafers
permanently bonded to borosilicate glass rings that have been
patterned according to the dimensions of the substrate.
⊲ Figure 5:Adapter debonding. ⊲
Adapter carrier wafer.
Silicon wafer on an imperforated glass carrier wafer.
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commercial micro manufacturing international Vol 11 No. 6 39
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substrates, for example, 150 mm wafers on 200 mm equipment. Even
multiple small substrates can be handled, for example, four 76 mm
wafers on a 200 mm carrier wafer.
Options are:
• glass carrier wafers with patterned pockets;
• silicon carrier wafers with patterned pockets; and
• silicon carrier wafers permanently bonded to glass rings.
Due to the materials used, these carrier wafers can be used in
operating temperatures up to 500˚C. In addition, holes or grooves
can be added to enable the use of adapter carrier wafers with
vacuum chucking. Unique marking by quick response (QR) codes can be
applied for easy tracking.
Conclusion
Carrier wafers made of glass, quartz or silicon are fundamental
tools for 3D wafer-level packaging of MEMS and sensors. Plan Optik
manufactures high-end glass, quartz and silicon carrier wafers for
many MEMS- and semiconductor-related processes. They can provide,
as outlined above, chemical and high-temperature resistance,
exceptionally low tolerances and thermal expansion adjusted to
silicon or other substrate materials. Furthermore, non-sticking or
sticking surface properties can be incorporated, and excellent
surface quality is achievable through double-sided polishing. ●
Plan Optik www.planoptik.com
http://www.planoptik.comhttp://www.sensofar.com
