SOURCE: IBM
September 17, 2008 13:00 ET
IBM Develops Computational Scaling Solution for Next Generation "22nm" Semiconductors
Semiconductor Breakthrough to Benefit Cloud Computing; Paves Way for Next-Gen Servers and Consumer Electronics Devices
ARMONK, NY--(Marketwire - September 17, 2008) - In response to ever increasing demands for
smaller, more powerful and energy-efficient devices for cloud computing and
high-performance servers, IBM (NYSE: IBM) today announced the semiconductor
industry's first computationally based process for production of next
generation 22nm semiconductors. Known as Computational Scaling (CS) -- a
process that enables the production of complex, powerful and
energy-efficient semiconductors at 22nms and beyond -- this new initiative
will feature support from several of IBM's key partners initially including
Mentor Graphics and Toppan Printing.
Today, most integrated circuits are manufactured at 45nm or larger
technology nodes. Producing circuits at 22nm is a challenging milestone
since current lithography methods -- the process of designing photomasks to
image circuit patterns on silicon wafers in mass quantity -- are not
adequate for critical layers at 22nm due to fundamental physical
limitations. Computational Scaling overcomes these limitations by using
mathematical techniques to modify the shape of the masks and
characteristics of the illuminating source at each layer of an integrated
circuit.
This initiative directly links to IBM's Cloud Computing strategy, which
offers highly scalable, more energy efficient Web services. Through cloud
computing, enterprises and individuals can access these services in a
highly flexible and open environment. As demand for these services grows,
more powerful and flexible servers based upon advanced technologies will be
required.
"The traditional scaling approach is optical-resolution centric," said Gary
Patton, vice president, IBM Semiconductor Research and Development Center.
"IBM's Computational Scaling approach is centered on advanced mathematical
techniques encapsulated in software tools that use high performance
computing systems. This technique also makes technology complexity
transparent to the designer and maximizes flexibility through integrated
flows and automation."
IBM's CS solution is an ecosystem that includes the following components: a
new resolution enhancement technique (RET) that uses source-mask
optimization (SMO); virtual silicon processing with TCAD; predictive
process modeling; design-rule generation and corresponding models; design
tooling; design enablement; complex illumination; variance control; and
mask fabrication, along with necessary partnerships.
The strategy of combining the strengths of industry leading partners for CS
will leverage IBM's core strengths in successful management of innovative
partnerships, semiconductor processing, high performance computing, IC
design, design tooling and system integration.
The individual components of IBM's CS solution include:
Source Mask Optimization
IBM has partnered with Mentor Graphics on a new resolution enhancement
technique to enable cost-effective printing of two dimensional patterns for
the 22nm semiconductor technology generation. This new technology, know as
source mask optimization, will provide a means to minimize the use of
double patterning by employing highly customized sources with optimized
mask shapes.
"Our partnership with IBM will ensure production-ready technologies are in
place when they are needed for the 22nm node," said Joseph Sawicki, vice
president and general manager for the design-to-silicon division at Mentor
Graphics. "Because this next generation solution will be built on the
familiar Calibre platform, designers will see a smooth transition path to
22nm, and will also enjoy added benefits in managing turnaround time and
the cost of computing."
Virtual Fabricator
Together with Rensselaer Polytechnic Institute and the State of New York,
IBM has made significant investments in the area of high performance
computing and remains devoted to the advancement of semiconductor
technology through the establishment of the Computational Center for
Nanotechnology Innovations (CCNI). CCNI provides the unprecedented
computational power to enable accurate predictions of advanced
manufacturing processes. When combined with predictive models and TCAD,
this platform will allow virtual co-optimization of semiconductor unit
processes and critical circuit design elements to cut development learning
cycles and improve time-to-market for advanced semiconductor technology.
Design Technology Co-Optimization
Within semiconductor fabrication, design 'rules' are created as an abstract
representation of the information or model that describes the technology
being created. Often, these rules are only defined after an exhaustive
negotiation process between the technology and design team. To improve the
timeliness and certainty of this process, IBM's Design Technology
Co-optimization (DTCO) process helps integrate and automate this complex
procedure, cutting the time it takes to reach a clear and stable set of
rules for use by the circuit design teams.
Design Enablement Tools
As a result of using IBM's DTCO, a semiconductor modeling process will have
a new class of design rules that are simpler and more prescriptive (what to
do vs. what not to do). Working with engineering design automation (EDA)
suppliers, IBM will be providing new design enablement solutions for a
seamless transition.
Critical Dimension Variance Control
Working with leading equipment suppliers, IBM will play the role of lead
integrator of providing an adaptive control system to minimize critical
dimension variance. As a result production yield and circuit parameters
will be more stable reducing the cost of production.
Photomask Fabrication
To address the gap in raw optical resolution, aggressive resolution
enhancement techniques such as SMO drive unprecedented minimum feature
sizes on the photomask -- the opaque plate with holes or transparencies
that allow light to shine through in a defined guide for casting the
circuit patterns. IBM has partnered with Toppan to ensure timely
availability of masks with the required feature sizes.
"It has been more than three years since Toppan and IBM launched our joint
development project for advanced photomask process," said Toshiro Masuda,
managing director and head of Semiconductor Solutions Division of Toppan
Printing. "We believe our ongoing engineering collaboration will
significantly enhance the success of IBM's computational scaling solution."
About IBM
For more information about IBM's semiconductor products and services, visit
www.ibm.com/technology.