SUNNYVALE, CALIF. AND KYOTO, JAPAN - June 12, 2003 - At the VLSI Symposium in Kyoto, Japan, AMD (NYSE: AMD) researchers presented detailed information on their creation of transistors delivering some of the highest performance levels ever published. Faster transistors are key enablers of higher-performance customer solutions, acting as the fundamental building blocks of future microprocessor designs.

One set of transistors presented today use fully-depleted Silicon-on-Insulator (FDSOI) technology and deliver the highest PMOS (P-channel metal-oxide semiconductor) transistor speed ever published: up to a 30% increase versus previously published transistors. The other set use Strained-Silicon and AMD metal gate technology to deliver 20-25% higher NMOS (N-channel metal-oxide semiconductor) performance relative to conventional Strained-Silicon transistors.

"Metal-gates, FDSOI and Strained-Silicon are examples of key transistor R&D work conducted by AMD. The double-digit percent improvements achieved in our labs expands AMD's options for achieving our aggressive performance objectives when we transition to 65 nanometer (nm) production and beyond," said Craig Sander, vice president of process technology development for AMD.

Technical Details

AMD's latest transistors utilize a new form of transistor gate technology pioneered by AMD. Rather than using Polysilicon, the gate material used in most transistors today, AMD researchers used a material called Nickel Silicide to make "metal gates" within the transistors. Transistor gates turn the flow of electrical current through the transistor on and off and are a key element of a transistor's structure.

AMD used a combination of its metal gates and FDSOI to create a PMOS transistor with significantly improved gate conductance, appropriately engineered workfunction and enhanced carrier mobility. The combination of these effects resulted in transistor speed up to 30 percent higher than any previously published PMOS data at the time of testing. Performance ratings are based on the industry standard benchmark used for calculating transistor switching speed. For complete technical details of the research, see http://www.amd.com/vlsi03_fdsoi.

AMD's combination of its metal gates with Strained-Silicon in an NMOS (N-Channel Metal Oxide Semiconductor) transistor demonstrated similarly positive effects on gate conductance, workfunction, and carrier mobility, in addition to the mobility enhancement resulting from the Strained-Silicon layer. A transistor performance increase of 20-25% was achieved over conventional Strained-Silicon devices at the time of testing. For complete technical details of the research, see http://www.amd.com/vlsi03strained_silicon.

"AMD's research also suggests Nickel Silicide or other metal gate technologies could eventually lead to solving key challenges in the further shrinking of transistors beyond the 65nm production node," added Sander. "Metal gate technologies provide a means to reduce the effective oxide thickness and alleviate the stringent requirements imposed on aggressive gate oxide scaling required for high performance transistors."

FDSOI and Strained-Silicon Details

Currently, SOI transistors are built on a thin top-layer of pure Silicon that sits atop another layer of insulating oxide. The insulating layer ensures that electrical current flows only through the thin top-layer of Silicon, and doesn't leak down into the material that forms the bulk of the wafer.

The thinness of the Silicon top-layer contributes to better transistor performance, in part because it minimizes undesirable electrical characteristics that could inhibit transistor operating efficiencies. Fully depleted SOI, an advance over today's SOI technologies, could offer higher performance capabilities thanks to a much thinner top-layer of Silicon.

Strained-Silicon transistors offer increased performance potential due to the Silicon atoms being "strained" to enhance carrier mobility, which results in improved electrical current flow. Emerging research shows that SOI and Strained-Silicon can be integrated within the same fabrication process to achieve additive benefits.

About AMD

Founded in 1969 and based in Sunnyvale, California, AMD (NYSE: AMD) is a global supplier of integrated circuits for the personal and networked computer and communications markets with manufacturing facilities in the United States, Europe, Japan, and Asia. AMD, a Standard & Poor's 500 company, produces microprocessors, Flash memory devices, and Silicon-based solutions for communications and networking applications.


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