GLOBALFOUNDRIES,
the world's first truly global leading-edge semiconductor manufacturing company,
today described an innovative technology that could overcome one of the key
hurdles to advancing high-k metal gate (HKMG) transistors, bringing the industry
one step closer to the next generation of mobile devices with more computing
power and vastly improved battery life.
The semiconductor industry is celebrated for overcoming seemingly insurmountable
odds to continue the trend toward smaller, faster, and more energy-efficient
products. Performed in partnership with IBM through GLOBALFOUNDRIES’ participation
in the IBM Technology Alliance, the new research is designed to enable the continued
scaling of semiconductor components to the 22 nanometer node and beyond.
At the 2009 Symposium on VLSI Technology in Kyoto, Japan, GLOBALFOUNDRIES reported
the first demonstration of a technique that allows the equivalent oxide thickness
(EOT) in a high-k metal gate (HKMG) transistor to scale down to well beyond
the level required for the 22nm node, while maintaining a combination of low
leakage, low threshold voltages, and superior carrier mobility.
“HKMG is a critical component of GLOBALFOUNDRIES’ technology roadmap,”
said Gregg Bartlett, senior vice president of technology and research and development.
“This development could eventually provide customers with another tool
to enhance the performance of their products, particularly in the fast-growing
market for ultra-portable notebooks and smartphones with extended battery life.
In conjunction with IBM and the alliance partners, we are tapping our global
knowledge base to develop advanced technologies that will allow our customers
to stay at the leading edge of semiconductor manufacturing.”
To maintain the switching precision of a HKMG transistor, the EOT of the high-k
oxide layer must be reduced. However, reducing the EOT increases the leakage
current, which can contribute to an increase in the power consumption of a microchip.
GLOBALFOUNDRIES and IBM have developed a new technique that overcomes this barrier,
demonstrating for the first time that EOT scaling to well beyond the 22nm node
can be achieved while maintaining the necessary combination of leakage, threshold
voltages, and carrier mobility. The results were successfully demonstrated through
fabrication of an n-MOSFET device with EOT of 0.55nm and a p-MOSFET with EOT
of 0.7nm.