May 17 2010
ATDF, a wholly owned subsidiary of SEMATECH, and The University of Texas at Austin (UT), have joined forces to create the Advanced Processing and Prototyping Center (AP2C), a highly specialized R&D program designed to speed leading-edge nanoelectronic technology to the marketplace.
The AP2C combines UT's world-class research with ATDF's leading-edge processing and SEMATECH's industry know-how, and builds on Texas' established reputation as a leader in the electronics industry. Funded with an approximately $5 million grant from the Defense Advanced Research Projects Agency (DARPA), the AP2C will investigate a wide range of revolutionary devices and materials which incorporate advanced microchip manufacturing technologies.
"The AP2C fits in well with the plans of Governor Perry and the UT System to develop a state and federal partnership for advancing nanotechnology in Texas," said Robert Barnhill, UT System vice-chancellor for Research and Technology Transfer.
Added Sanjay Banerjee, director of the UT Microelectronics Research Center and lead university researcher for the AP2C: "This new center is an excellent way to encourage promising research ideas, develop them, and then accelerate the best ones to quicken the pace of technology."
"Continuous advancements in leading edge and emerging technology areas are critical for future generations of the even more intense information-processing and storage needed to enable personalized medicine, on-demand entertainment, fully virtualized retail commerce, and the most sophisticated military and homeland security systems," said Dave Anderson, ATDF general manager.
The AP2C will be distributed physically within existing offices and labs at UT Austin, UT Dallas, SEMATECH, and ATDF. It will involve the efforts of approximately 200 professors, graduate students, engineers, and manufacturing technicians, significantly leveraging the regional nanoelectronics research infrastructure.
"With the AP2C, we have added another dynamic and innovative R&D resource to our portfolio of leading-edge development," said Anderson. "Here we can develop and test the new materials and innovative device structures and processing methods that will enable the electronics industry to accelerate, as well as drive the spillover benefits into other industries, such as biotechnology and energy."
The AP2C will help enable R&D for many new technologies and products, including:
- Development and evaluation of nanoimprint technology, a revolutionary approach that could dramatically lower the cost of producing nanotechnology products, including electronic and biomedical devices
- Techniques needed to build "electronic noses," devices that have the ability to sense harmful chemicals, spoiled food, and illegal drugs
- New types of computer chips made of novel materials and structures, enabling faster communications devices that generate less heat and need less power to operate
- Advances in electron microscopes for the measurements required to develop next-generation nano-manufacturing tools and processes
AP2C Technical Details
The AP2C will complement work begun in 2004 at the Advanced Materials Research Center (AMRC), a state-funded, cooperative program between SEMATECH and Texas universities. ATDF, a leading advanced nanoscale manufacturing research facility, will offer accelerated production assessments of the most promising experimental devices and structures emerging from AP2C university projects.
Overall, AP2C projects will involve use of nanowires, silicon-germanium-carbon structures, imprint lithography, and substrates composed of high-mobility compound semiconductors bonded with silicon for advanced complementary metal oxide semiconductor (CMOS) technology. Other targeted technologies will include directed self-assembly for patterning, hybrid composite materials, spintronics memory, quantum transport and optical interconnects.
Specific AP2C projects initially will include:
- Fabrication of nanoscale field-effect transistors (FETs) composed of germanium nanowires
- Incorporation of carbon in silicon and germanium substrates to enable III-V compound semiconductors to be incorporated in semiconductor devices on a silicon wafer
- Step-and-flash imprint lithography, a revolutionary technology which uses a mold-like template to "stamp" extremely small structures into microchips or other nanotechnology or biotechnology devices
- Circuit patterning through directed self-assembly, an experimental way of "growing" circuit patterns directly on a chip
- Quantum transport, based on quantum mechanics to model the movement of electrons through nanoelectronics device switches
- Optical interconnects, involving the use of lasers instead of copper or other metals to connect devices on a chip
"AP2C will help define the future shape of nanoelectronics, and will allow our industry and other industries that have traditionally benefited from advancements in smaller, faster, innovative chip manufacturing capabilities, to continue accelerating forward," said Randy Goodall, director of External Programs for SEMATECH. "The resulting productivity in research, manufacturing, business and personal life will, in turn, benefit the industries and careers of the future -- keeping Texas in the race for leadership in technology innovation."
Source: http://www.atdf.com/