More than three decades ago,
Moore's Law predicted IC
development would one day
come to a halt, since the fundamental laws of physics
would keep chips from shrinking any further. Though that prognostication hasn't come true yet, two surprising
factors previously not considered are
throwing up roadblocks to further breakthroughs—packaging and interconnects.
Both have been driving IC process,
assembly, and form factor developments,
enabling designers to scale down chip line
geometries to the tiniest of dimensions.
Still, formidable challenges lie ahead as
ICs dwindle in size. Testing and packaging
costs are rising. In fact, they can cost as
much as the die the IC is made on, if not
higher, representing a significant portion of
the IC's overall cost.
Steps in IC design are merging within the
product-development cycle. It's becoming
more common to simultaneously craft an
IC chip, its package, and the board it's
mounted on. Of course, there are the power requirements for ICs designed with 90nm line widths and below. Thus, designers
must also account for IR voltage drops in
the package and include them in the overall design optimization. Then, add in the
concomitant rising heat-dissipation levels
for smaller chip and interconnect areas,
which demands more sophisticated heatmanagement techniques. It all makes for a
challenging task, indeed.
To increase packing densities, IC manufacturers are clamoring for advanced manufacturing and packaging techniques, such as wafer thinning, system-on-a-chip (SoC),
chip and board stacking, system in package
(SiP), chip-scale packaging (CSP), wafer-level
chip-scale packaging (WLCSP), multichip
packaging (MCP), and package on a package (PoP). All these 3D approaches strive for
greater densities through the vertical Z axis.
PoP and WLP represent two of the
hottest 3D packaging technologies. Until
recently, WLP was limited to ICs with less
than 20 pins. Using more pins tended to
trigger reliability problems, caused by differences in the thermal coefficients of
expansion between the silicon ICs and the
pc boards on which they were mounted.
New WLP technologies promise packaging
of ICs with up to 100 pins.
Tessera Technologies has announced
one of the thinnest WLCSP products, coming in at a mere 0.5 mm (). Aimed at
companies developing advanced electronics with integrated cameras, it's built on
Tessera's Shellcase technology's innovative packaging approach.
Many 3D packaging approaches are
being pursued. Whether or not designers
stack chips and die on top of each other or
place them as separate die, interconnecting them in a single package can lead to
different reliability and yield results. These
varied results are largely influenced by the
types of chips and dies involved, the complexity of interconnecting them, and the
intended application.
Samsung Electronics Co. devised an
ultra-thin (1.4 mm) 16-chip stack of NAND
flash memory in an MCP (). Each
wafer is thinned to 95% of its original thickness (as used in a previous-generation MCP) to produce an overall thickness of 30
mm. The company then trimmed an adhesive layer used between each chip and the
next one from 60 to 20 mm.
Ziptronix's Direct Bond Interconnect (DBI)
technology enables scalable, high-density,
electrical interconnects bonded in a die-towafer scale method. DBI achieves the highest density of electrical connections for 3D
ICs—4 million connections/cm2 (). It
represents an advance of Ziptronix's ZiROC
direct bond technology, which enables
covalent, room-temperature bonds
between the silicon-oxide surfaces of each
chip in the 3D structure.
IMEC has pioneered many 3D packaging
concepts for a number of wireless, medical, consumer, and other applications,
including SiP, WLP, and a unique stacked-IC
(SIC) concept (). In the SIC, small silicon vias with copper nails are used before
the front-of-the-line process step.