United States : Agilent Technologies and Stanford University to Explore New Class of Nanoscale Devices.Byline: pinto03 Agilent Technologies Inc. (NYSE NYSE See: New York Stock Exchange : A) today announced it is collaborating with Stanford University in a research program designed to explore a new class of nanoscale devices using a combinations of the scanning probe microscope (SPM SPM - Sequential Parlog Machine ) and 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. (ALD ALD abbr. adrenoleukodystrophy ALD, n.pr See adrenoleukodystrophy. ALD aldolase. ). The research will enable the rapid prototyping and characterization of nanoscale devices with breakthroughs in sub 10 nm scale for a wide range of applications. The novel nanostructures will be fabricated and characterized in-situ in this unique SPM-ALD tool in order to rapidly prototype a wide variety of next-generation devices, said Fritz Prinz, professor and chairman, mechanical engineering, Stanford University. The SPM-ALD tool will enable us to build devices which take advantage of the quantum confinement effects present at small length scales, length scales that could not be accessed with traditional lithography methods. These devices can only be built with manufacturing tools possessing extraordinary spatial resolution (Data West Research Agency definition: see GIS glossary.) A measure of the accuracy or detail of a graphic display, expressed as dots per inch, pixels per line, lines per millimeter, etc. It is a measure of how fine an image is, usually expressed in dots per inch (dpi). . This program focuses on the integration of ALD, a thin-film technique capable of sub-nanometer precision in thickness, with the nanometer lateral resolution SPM in a drive to extend the capability of scanning probe techniques to prototyping and device fabrication fabrication (fab´rikā´sh  n),n the construction or making of a restoration. . Historically, performance of electronic devices has been limited by traditional manufacturing methods, such as optical and electron beam lithography Using electron beams to create the mask patterns directly on a chip. The wavelength of an electron beam is only a few picometers compared to the 248 to 365 nanometer wavelengths of light used to create the traditional photomasks. , which are not likely to deliver feature resolution significantly below 20 nm. However, the quantum mechanical effects of electron confinement in devices 10 nm or smaller result in phenomena qualitatively different than those seen in larger devices. Taking advantage of this quantum confinement is predicted to result in a new paradigm New Paradigm In the investing world, a totally new way of doing things that has a huge effect on business. Notes: The word "paradigm" is defined as a pattern or model, and it has been used in science to refer to a theoretical framework. for electronic devices. We chose Stanford University for this grant for the recognized expertise of professor Prinz and team, and the close alignment between the proposed research and the future of Agilent s SPM business, said Jack Wenstrand, Agilent s director of university relations. The work between Agilent and Stanford University is part of Agilent s University Relations Program : , which facilitates collaborations with universities around the world. Agilent supports scientific work with universities worldwide through direct grants and collaborative research. Copyright : Euclid Infotech Pvt. Ltd. Provided by Syndigate.info an Albawaba.com company |
|
||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion