Philips Highlights Leading Consumer-Oriented Semiconductor R&D at IEDM 2004.SAN JOSE, Calif. -- Record-breaking performance of 90-nm RF CMOS (Complementary Metal Oxide Semiconductor) Pronounced "c-moss." The most widely used integrated circuit design. It is found in almost every electronic product from handheld devices to mainframes. process takes advanced development to new levels At this year's IEEE (Institute of Electrical and Electronics Engineers, New York, www.ieee.org) A membership organization that includes engineers, scientists and students in electronics and allied fields. International Electron Devices Meeting The International Electron Devices Meeting is an annual conference held alternatively in San Francisco, California and Washington D.C. Established in 1954, IEDM is the world's main forum on advancement in semiconductor and electronic devices. (IEDM IEDM International Electron Devices Meeting IEDM Institute Économique de Montréal , San Francisco, USA, 13 - 15 December 2004), Philips' R&D scientists will be contributing to no less than 17 different papers on advanced semiconductor research and development. Detailing R&D carried out by Philips in collaboration with IMEC (Belgium) and the Crolles2 Alliance (a partnership between Philips, Freescale Semiconductor and STMicroelectronics) the majority of these papers cover CMOS process development at the 65-nm and 45-nm nodes, and record-breaking RF CMOS performance at the 90-nm node. The primary focus for Philips is the development of advanced CMOS processes that are compatible with the high-volume low-cost manufacturing requirements of consumer-product applications. "There is no point in having the most advanced semiconductor processes in the world if you cannot deliver them at the price points demanded by your customers," said Fred van Roosmalen, general manager technology partnerships, Philips Semiconductors. "With our extensive heritage in consumer electronics, our own world-class research facilities and our close partnership with some of the world's other leading semiconductor companies and research institutes, we are ideally placed to continue creating silicon solutions that meet the price/performance ratios demanded by the consumer-electronics industry." In preparation for continued process development within the Crolles2 Alliance, Philips closely collaborates with IMEC on advanced CMOS technologies. This leading-edge research collaboration on the critical challenges in CMOS scaling keeps Philips in a highly competitive position at the forefront of the semiconductor industry. It is the success of the semiconductor industry in keeping pace with Moore's Law - the prediction that the number of transistors on a given area of silicon doubles roughly every two years - that has been responsible for driving down the cost and enhancing the performance of everyday products such as DVD players, digital cameras and mobile phones. Although migration from 90-nm to 65-nm should be possible using technology similar to today's, hitting the 45-nm and 32-nm targets on the ITRS ITRS International Technology Roadmap for Semiconductors ITRS International Terrestrial Reference System ITRS International Transaction Reporting System (EU) ITRS International Technical Rescue Symposium roadmap poses considerable challenges for the semiconductor industry. As the thickness of the transistors' gate oxide is scaled in line with their channel length, leakage currents through an oxide layer only a few atoms thick threatens to reverse the reduced power consumption normally associated with migration from one CMOS technology node to the next. In addition, the use of new materials such as high-k dielectrics to overcome gate leakage, low-k dielectrics to reduce interconnect capacitance and new metals to replace polysilicon gates considerably increases process complexity. For semiconductor companies serving the consumer electronics industry, this makes it increasingly important that technology improvements continue to be compatible with high-volume manufacturing methods. In addition to highlighting leading research into metal and fully-silicided gate structures, a number of the IEDM papers contributed to by Philips examine ways of minimizing the impact of new materials or manufacturing steps on process complexity and cost. Another important area where new semiconductor technologies are set to make their mark is in RF applications. At the 90-nm node, CMOS transistors have excellent RF performance, allowing them to rival silicon bipolar solutions in some areas of mobile communications and wireless networking. Philips is presenting a paper at this year's IEDM that highlights the record-breaking performance of its 90-nm RF CMOS process. It is also presenting papers on new metal-emitter SiGe:C HBTs (Heterojunction Bipolar Transistors) that will enable low-cost silicon-based transceivers for mm-Wave (greater than 30 GHz) wireless applications; new substrate isolation techniques to improve the RF performance of on-chip passive components; and new methods of modeling RF MOSFET (Metal Oxide Semiconductor Field Effect Transistor) The most popular and widely used type of field effect transistor (see FET). MOSFETs are either NMOS (n-channel) or PMOS (p-channel) transistors, which are fabricated as individually packaged devices. A complete list of the IEDM papers to which Philips and IMEC have contributed are listed below: Baseline CMOS related: A 0.314micrometer micrometer (mīkrŏm`ətər, mī`krōmē'tər). 1 Instrument used for measuring extremely small distances. 2 6T-SRAM Cell Build With Tall Triple-Gate Devices for 45nm Node Applications Using 0.75NA 193nm Lithography A Capacitor-less DRAM Cell on 75nm Gate Length, 16nm Thin Fully Depleted SOI Device for High Density Embedded Memories Work Function Tuning Through Dopant dopant Any impurity added to a semiconductor to modify its electrical conductivity. The most common semiconductors, silicon and germanium, form crystalline lattices in which each atom shares electrons with four neighbours (see bonding). Scanning and Related Effects Ni Fully Silicided Gate for Sub-45nm Nodes CMOS Diffusion-less Junctions and Super Halo Profiles for PMOS (Positive channel MOS) Pronounced "p-moss." A type of microelectronic circuit in which the base material is positively charged. PMOS transistors were used in the first microprocessors and are still used in CMOS. Transistors Formed by SPER and FUSI FUSI First Union Securities, Inc. FUSI Fully-Silicided Gate in 45 nm Physical Gate Length Devices "On-the-fly" Characterization of NBTI NBTi News by Teens International (website) NBTI Negative Biased Temperature Instability in Ultra-Thin Gate-Oxide PMOSFETs Poly-Gate REplacement Through Contact Hole (PRETCH): A New Method for High-K/Metal Gate and Multi-Oxide Implementation on Chip Demonstration of an Extendable and Industrial 300mm BEOL BEOL Back-End-Of-Line BEOL Bent's Old Fort National Historic Site (La Junta, Colorado) BEOL Bent's Old Fort National Historic Site (US National Park Service) Integration for 65nm Technology Node Integration of ALD ALD abbr. adrenoleukodystrophy ALD, n.pr See adrenoleukodystrophy. ALD aldolase. TaN Barriers in Porous Low-k Interconnect for the 45nm Node and Beyond; Solution to Relax Electron Scattering Effect A Conventional 45nm CMOS Node Low-Cost Platform for General Purpose and Low Power Applications SON (Silicon-On-Nothing) Technological CMOS Platform: Highly Performant Devices and SRAM See static RAM. SRAM - static random-access memory Cells A New Dynamic Cell-Based Performance Metric for Novel CMOS Device Architectures Gate Stack Optimization for 65nm CMOS Low Power and High Performance Platform 45nm nMOSFET with Metal Gate on Thin SiON Driving 1150microampere/micrometer and Off-state of 10microampere/micrometer Electrical Deactivation de·ac·ti·vate tr.v. de·ac·ti·vat·ed, de·ac·ti·vat·ing, de·ac·ti·vates 1. To render inactive or ineffective. 2. To inhibit, block, or disrupt the action of (an enzyme or other biological agent). 3. and Diffusion of Boron in Preamorphized Ultrashallow Junctions: Interstitial Transport and F Co-Implant Control Note: the research outlined in several of the above papers was partially funded under the European Union's IST NANOCMOS project (an integrated project in the EU's Information Society Technologies priority) or as part of the MEDEA Medea (mĭdē`ə), in Greek mythology, princess of Colchis, skilled in magic and sorcery. She fell in love with Jason and helped him, against the will of her father, Aeëtes, to obtain the Golden Fleece. + framework. RF Related: Metal Emitter SiGe:C HBTs New Low-Cost Thermally Stable Process to Reduce Silicon Substrate Losses: A Way to Extreme Frequencies for High Volume Si Technologies Capacitance Modeling of Laterally Non-Uniform MOS Devices About IMEC IMEC is a world-leading independent research center in nanoelectronics and nanotechnology. Its research focuses on the next generations of chips and systems, and on the enabling technologies for ambient intelligence. IMEC's research bridges the gap between fundamental research at universities and technology development in industry. Its unique balance of processing and system know-how, intellectual property portfolio, state-of-the-art infrastructure and its strong network of companies, universities and research institutes worldwide, position IMEC as a key partner with which to develop and improve technologies for future systems. IMEC is headquartered in Leuven, Belgium and has representatives in the US, China and Japan. Its staff of more than 1300 people includes over 380 industrial residents and guest researchers. In 2003, its revenues were EUR EUR In currencies, this is the abbreviation for the Euro. Notes: The currency market, also known as the Foreign Exchange market, is the largest financial market in the world, with a daily average volume of over US $1 trillion. 145 million. Further information on IMEC can be found at www.imec.be. About Royal Philips Electronics Royal Philips Electronics of the Netherlands (NYSE NYSE See: New York Stock Exchange :PHG)(AEX AEX See: Amsterdam Exchange :PHI) is one of the world's biggest electronics companies and Europe's largest, with sales of $32.8 billion (EUR 29 billion in 2003). With activities in the three interlocking domains of healthcare, lifestyle and technology and 166,800 employees in more than 60 countries, it has market leadership positions in medical diagnostic imaging and patient monitoring, color television sets, electric shavers, lighting and silicon system solutions. News from Philips is located at www.semiconductors.philips.com. |
|
||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion