Wafer fabrication

http://dbpedia.org/resource/Wafer_fabrication an entity of type: AnatomicalStructure

Wafer fabrication is a procedure composed of many repeated sequential processes to produce complete electrical or photonic circuits on semiconductor wafers in semiconductor device fabrication process. Examples include production of radio frequency (RF) amplifiers, LEDs, optical computer components, and microprocessors for computers. Wafer fabrication is used to build components with the necessary electrical structures. These steps are often repeated many hundreds of times, depending on the complexity of the desired circuit and its connections. rdf:langString
rdf:langString Wafer fabrication
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rdf:langString Simplified illustration of the process of fabrication of a CMOS inverter on p-type substrate in semiconductor microfabrication. Each etch step is detailed in the following image. Note: Gate, source and drain contacts are not normally in the same plane in real devices, and the diagram is not to scale.
rdf:langString CMOS_fabrication_process.svg
rdf:langString Photolithography_etching_process.svg
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rdf:langString Wafer fabrication is a procedure composed of many repeated sequential processes to produce complete electrical or photonic circuits on semiconductor wafers in semiconductor device fabrication process. Examples include production of radio frequency (RF) amplifiers, LEDs, optical computer components, and microprocessors for computers. Wafer fabrication is used to build components with the necessary electrical structures. The main process begins with electrical engineers designing the circuit and defining its functions, and specifying the signals, inputs/outputs and voltages needed. These electrical circuit specifications are entered into electrical circuit design software, such as SPICE, and then imported into circuit layout programs, which are similar to ones used for computer aided design. This is necessary for the layers to be defined for photomask production. The resolution of the circuits increases rapidly with each step in design, as the scale of the circuits at the start of the design process is already being measured in fractions of micrometers. Each step thus increases circuit density for a given area. The silicon wafers start out blank and pure. The circuits are built in layers in clean rooms. First, photoresist patterns are photo-masked in micrometer detail onto the wafers' surface. The wafers are then exposed to short-wave ultraviolet light and the unexposed areas are thus etched away and cleaned. Hot chemical vapors are deposited on to the desired zones and baked in high heat, which permeate the vapors into the desired zones. In some cases, ions, such as O2+ or O+, are implanted in precise patterns and at a specific depth by using RF-driven ion sources. These steps are often repeated many hundreds of times, depending on the complexity of the desired circuit and its connections. New processes to accomplish each of these steps with better resolution and in improved ways emerge every year, with the result of constantly changing technology in the wafer fabrication industry. New technologies result in denser packing of minuscule surface features such as transistors and micro-electro-mechanical systems (MEMS). This increased density continues the trend often cited as Moore's Law. A fab is a common term for where these processes are accomplished. Often the fab is owned by the company that sells the chips, such as Intel, Texas Instruments, or Freescale. A foundry is a fab at which semiconductor chips or wafers are fabricated to order for third party companies that sell the chip, such as fabs owned by Taiwan Semiconductor Manufacturing Company (TSMC), United Microelectronics Corporation (UMC), GlobalFoundries and Semiconductor Manufacturing International Corporation (SMIC). In 2013 the cost of building the next generation wafer fab was over $10 billion.
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