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COSMOS Summer 2008 Chips and Chip Making Rajesh K. Gupta Computer Science and Engineering University of California, San Diego. ©2008 R. Gupta, UCSD Roadmap • Topic: – Integrated circuit chips • This lecture – IC Chips, Chip making ingredients and steps. • Reference – “How chips are made” – Intel Keywords: http://www.intel.com/education/makingchips/index.htm – “Microelectronics 101” – IBM http://www-306.ibm.com/chips/technology/makechip ©2008 R. Gupta, UCSD The Chip: A Packaged Part Quad Flat Pack (QFP) Ball Grid Array (BGA) http://education.netpack-europe.org/chipp.php The Die Under a Microscope Intel 4004 (‘71) Intel 8080 Intel 8286 Intel 8085 Intel 8486 A Gate Layout Defines a set of “masking layers” for printing purposes. The Ingredients • Silicon Wafers cut from an ingot of pure silicon. • Chemicals and gases are used throughout the chipmaking process. • Metals, such as aluminum and copper, are used to conduct the electricity throughout the microprocessor. Gold is also used to connect the actual chip to its package. • Ultraviolet (UV) Light has very short wavelengths and is just beyond the violet end of the visible spectrum. • Masks used in the chip-making process are like stencils. When used with UV light, masks create the various circuit patterns on each layer of the chip. [Courtesy Intel. Adapted from http://www.intel.com/education/teachtech/learning/chips/preparation.htm] Building Chip • Start with a disk of silicon called wafer • 75 mm to 300 mm in diameter, < 1 mm thick • cut from ingots of single-crystal silicon • pulled from a crucible of pure molten polycrystalline silicon using a seed crystal • Different processing steps and techniques • • • • Introduce dopants Oxidation Masking Polysilicon Introduce Dopants • Pure silicon is a semiconductor • bulk electrical resistance in between that of a conductor and insulator • Conductivity of silicon can be varied several orders of magnitude by introducing impurity atoms • called dopants • acceptors: accept electrons to leave holes in silicon • lead to p-type silicon (e.g. Boron) • donors: provide electrons to silicon • lead to n-type silicon (e.g. Arsenic, Phosphorous) Introduce Dopants (2) • Deposition through diffusion – evaporating dopant material into the silicon surface – thermal cycle: impurities diffuse deeper into material • Ion Implantation – silicon surface subjected to highly energized donor or acceptor atoms • atoms impinge silicon surface, and drive below it to form regions of varying concentrations Ion Implantation Oxidation • • Method 1: Heating silicon wafers in an oxidizing atmosphere (O2 or H2O) • Consumes Si • Grows equally in both vertical directions Method 2: Deposition • Deposited on top of existing layers Masking • Masks act as barrier against e.g. • ion implantation • dopant deposition before diffusion (dopants do not reach surface) • oxidation (O2 or H2O does not reach surface) • Commonly used mask materials • photoresist • polysilicon • silicon dioxide (SiO2) • silicon nitride (SiN) Example: oxide mask a. bare silicon wafer b. oxidize wafer c. deposit layer of photoresist d. expose the photoresist selectively to UV light • The drawn mask pattern determines which part is exposed • Resist polymerizes where exposed e. unexposed resist is removed with solvent: negative resist (positive resist: exposed resist is removed) f. exposed oxide is etched g. photoresist is washed off h. the oxide can now be used as a masking layer for ion implantation The Printing Challenge UV lithography: line width limited by diffraction and alignment tolerances, but tricks are used Electron beam lithography has emerged: directly from digital data, but more costly and slow Polysilicon • Silicon also comes in a polycrystalline form • called polysilicon, or just poly • high resistance • normally doped at the same time as source/drain regions • Used as • an interconnect in silicon ICs • gate electrode in MOS transistors • most important: acts as a mask to allow precise definition of source and drain extension under gate • minimum gate to source/drain overlap improves circuit performance (why?) • called self-aligned process The Design Process Packaging Single die Wafer From http://www.amd.com