Agere Systems Researchers Report Semiconductor Industry's Smallest Transistors With a Novel Gate Insulator Material.Business/High Tech Editors WASHINGTON--(BUSINESS WIRE)--Dec. 3, 2001 New Material Aimed At Significantly Reducing Power Used by Silicon Chips as Transistor Miniaturization Continues to Follow Moore's Law Moore's Law An observation, In 1965, by Intel co-founder Gordon Moore. He noticed the number of transistors per square inch on integrated circuits had doubled every year since their invention. Moore predicted the trend would continue for the foreseeable future.Although the pace has slowed, the number of transistors per square inch has since doubled approximately every 18 months. This is used as the current definition of Moore's Law. Researchers at Agere Systems (NYSE:AGR.A), the world leader in communications components, today reported that they have built the semiconductor industry's smallest transistors that incorporate a novel insulating material aimed at significantly reducing the power used by silicon chips. The new transistors use hafnium Hf oxide instead of traditional silicon dioxide (SiO2) A hard, glassy mineral found in such materials as rock, quartz, sand and opal. In MOS chip fabrication, it is used to create the insulation layer between the metal gates of the top layer and the silicon elements below. as the gate insulator A material that does not conduct electricity. Contrast with conductor. -- a thin layer in a transistor that separates the gate, which turns current flow on and off, from the channel through which current flows. A metallic element found with zirconium and used in nuclear reactor control rods and in tungsten alloys used in filaments. Atomic number 72. In recent years, the semiconductor industry has investigated many so-called high dielectric constant, or "high-k," materials for use as the gate insulator in future generations of integrated circuits. Hafnium oxide is one of the most promising of these novel materials. As today's silicon dioxide layers are made thinner to support higher switching speeds for enhanced IC performance, they are becoming more prone to letting electrons leak through -- causing increased power consumption and ultimately destroying transistor operation. Gate insulators based on high-k materials can be made thicker to block electron leakage while still enabling high switching speeds. In a paper presented here at the International Electron Devices Meeting (IEDM IEDM - International Electron Devices Meeting), Agere researcher Jack Hergenrother described how he and colleagues Glen Wilk, Tanya Nigam and others incorporated a uniform layer of hafnium oxide (HfO2) with polysilicon gate electrodes in a vertical replacement-gate (VRG VRG - Vaccinia-Rabies Glycoprotein (gene) VRG - Varig (Viacao Aerea Rio-Grandense, Brazil, ICAO code) VRG - Vegetarian Resource Group VRG - Ventral Respiratory Group VRG - Vision Research Group VRG - Vortex Ring Gun) transistor. The VRG transistor is an innovative device structure that the scientists pioneered two years ago while affiliated with Bell Labs, the research and development arm of Lucent Technologies. Agere's VRG devices have gate lengths of 50 nanometers -- about half the size of conventional planar transistors fabricated in today's leading-edge IC processes. The semiconductor industry has identified the VRG transistor as one of the leading novel device structures that might one day supersede the conventional planar transistor, to further extend transistor miniaturization as described by "Moore's Law." "Our VRG structure provides a practical way to achieve very small gate lengths with precise control, but we had to solve the gate insulator leakage issue to maintain the structure's promise for a broad variety of applications in upcoming IC generations," said Hergenrother. "The challenge was that the device's geometry makes it inherently more difficult to incorporate high-k gate insulators. Now we've successfully introduced a uniform layer of hafnium oxide using a manufacturable deposition technique, and the devices show greatly reduced leakage -- at least 100,000 times less than found with silicon dioxide." The deposition technique that Agere's researchers used is known as atomic layer deposition A semiconductor manufacturing technique that deposits a single layer on a chip that is only one atom or one molecule thick. As elements on a chip decreased to below 100 nm, this essential technology for making the chip ever smaller became commercial after the turn of the 21st century. For example, Applied Materials introduced its first atomic layer deposition chamber in 2001. (ALD ALD - À l'Attention De ALD - Academy of Laser Dentistry ALD - Accelerated Life Data ALD - Accounting Line Designator ALD - Acoustic Leak Detection ALD - Acquisition Logistics Division ALD - Acquisition Logistics Documents ALD - Adrenoleukodystrophy (genetic disease) ALD - Adults with Learning Difficulties (social services) ALD - Advanced Laser Designator ALD - Air Lift Division ALD - Airborne Laser Demo ALD - airborne laser designator (US DoD)). The depositions were performed by engineers at ASM America, a subsidiary of ASM International and a leading supplier of semiconductor wafer processing equipment, using ASM's Polygon(TM) gate stack cluster tool to provide the ALD process. ALD provides outstanding conformality -- meaning that the deposited layer has the same thickness on all surfaces even in deep trenches or narrow cavities -- a key requirement for the successful incorporation of hafnium oxide in the VRG structure. "The excellent conformality of ALD can be illustrated by considering how water condenses on an object such as a drinking glass," said Hergenrother. "If you chill a glass and then move it to a humid environment, water will initially condense evenly over all of the outside and inside surfaces. Other less conformal deposition techniques are like trying to wet the glass using a spray bottle -- surfaces facing the sprayer get soaked while other surfaces remain dry." Agere's transistors are among the industry's first with hafnium oxide deposited by ALD, widely considered a highly viable deposition technique for manufacturing when high-k materials become commercially attractive. Until now, the technique's suitability for use with novel transistor structures such as the VRG had not been demonstrated. Since the VRG transistor provides a very challenging geometry for gate insulator deposition, Agere's researchers believe their achievement demonstrates that ALD should be well-suited to any conventional or novel silicon-based transistor structure. Another notable result of Agere's research is that they achieved these low gate leakage currents with a polycrystalline high-k gate insulator -- in which atoms are aligned in a more orderly fashion than in amorphous insulators such as silicon dioxide. Polycrystalline gate insulators are generally more prone to letting electrons leak through, but their use provides greater flexibility in the overall semiconductor fabrication process. According to Hergenrother, these results suggest that with hafnium oxide, an amorphous dielectric may not be necessary to meet gate insulator leakage requirements, although reliability and yield issues require further investigation. The complete text of the Agere Systems paper, the associated technical presentation, and other supporting materials are available at http://www.agere.com/iedm2001. Agere Systems is the world's No. 1 provider of components for communications applications with leadership in optical components and integrated circuits. This dual capability uniquely positions Agere to deliver integrated solutions that form the building blocks for advanced wired, wireless, and optical communications networks. Agere also designs and manufactures a wide range of semiconductor solutions for communications-related devices used by consumers such as cellular phones, modems, and hard disk drives for personal computers and workstations. In addition, the company supplies complete wireless computer networking solutions through the ORiNOCO(TM) product line. More information about Agere Systems is available from its Web site at http://www.agere.com. This release contains forward-looking statements based on information available to Agere as of the date hereof. Agere's actual results could differ materially from the results stated or implied by such forward-looking statements due to a number of risks and uncertainties. These risks and uncertainties include, but are not limited to, completion of the distribution of Agere stock by Lucent Technologies Inc., customer demand for our products and services, control of costs and expenses, timely completion of employment reductions and other restructuring activities, price and product competition, keeping pace with technological change, dependence on new product development, reliance on major customers and suppliers, availability of manufacturing capacity, components and materials, general industry and market conditions and general domestic and international economic conditions including interest rate and currency exchange rate fluctuations. For a further discussion of these and other risks and uncertainties, see the prospectus filed by Agere with the Securities and Exchange Commission on March 28, 2001, and Agere's subsequent reports on Form 10-Q. Agere disclaims any intention or obligation to update or revise any forward-looking statements, whether as a result of new information, future events or otherwise. |
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