The difference between monocrystalline silicon and polysilicon

The difference between monocrystalline silicon and polysilicon is that when the molten silicon is solidified, the silicon atoms are arranged in a diamond crystal lattice into a plurality of crystal nuclei, and if these crystal nuclei grow into chips having the same crystal plane orientation, single crystal silicon is formed. If these crystal nuclei grow into chips with different crystal orientations, polysilicon is formed. The difference between polysilicon and monocrystalline silicon is mainly manifested in the physical properties. For example, in terms of mechanical properties, electrical properties, etc., polysilicon is not as good as monocrystalline silicon. Polysilicon can be used as a raw material for drawing monocrystalline silicon. Monocrystalline silicon can be regarded as the purest substance in the world. General semiconductor devices require silicon purity of more than six. The requirements for large-scale integrated circuits are higher, and the purity of silicon must reach nine nines. At present, people have been able to produce a single crystal silicon with a purity of twelve nines. Monocrystalline silicon is an indispensable basic material in modern science and technology such as electronic computers and automatic control systems.

High-purity silicon is extracted in quartz. For example, monocrystalline silicon is extracted through the following process: quartz sand, a metallurgical grade silicon, purified and refined, and a deposited polycrystalline silicon ingot, a monocrystalline silicon, and a silicon wafer are cut.

The refining of metallurgical grade silicon is not difficult. It is mainly made by reducing quartz sand with carbon in an electric arc furnace. The purity of the silicon thus recovered is about 98-99%, but the silicon used in the semiconductor industry must also be highly purified (the purity of the electronic grade polysilicon requires 11 9 and the solar cell grade only requires 6 9). In the purification process, a key technology of “trichlorosilane reduction method (Siemens method)” has not been mastered in China. Without this technology, more than 70% of the polysilicon in the refining process in China is emitted through chlorine. Not only the refining costs are high, but the environmental pollution is very serious. Every year, China extracts a large amount of industrial silicon from quartz stones and exports them to countries such as Germany, the United States, and Japan at a price of US$1 per kilogram. These countries process industrial silicon into high-purity crystalline silicon materials for US$46-80. / Kilogram price sold to our solar energy companies.

After high-purity polycrystalline silicon is obtained, it is smelted in a single crystal furnace into single crystal silicon, which is then sliced ​​and used for manufacturing of integrated circuits.

What is monocrystalline silicon can be used for the production and deep processing of diode-level, rectifier-level, circuit-level, and solar cell-level single crystal products. Its subsequent product-integrated circuits and semiconductor separation devices have been widely used in various fields in military electronics. Equipment also occupies an important position.

With the rapid development of photovoltaic technology and micro-miniaturized semiconductor inverter technology, solar cells produced using silicon single crystals can directly convert solar energy into light energy, realizing the beginning of the green energy revolution. The Beijing 2008 Olympic Games will showcase the “Green Olympics” as an important showcase for the world. The use of monocrystalline silicon will be an important part of this. Now, foreign solar photovoltaic power plants have reached the stage of theoretical maturity and are transitioning to the practical application stage. The utilization of solar silicon monocrystals will be universally available and the market demand is self-evident. The single crystal silicon industrial park in Ningjin, Hebei, responds to this international trend and provides the world with single crystal silicon products with excellent performance and complete specifications.

Monocrystalline silicon products include φ3”----φ6” monocrystalline silicon round rods, sheets and square rods, and are suitable for the production of various semiconductor and electronic products. Their product quality has passed the most advanced detection in the world. The instrument is tested to the world's advanced level.

Application programs are normally developed in the CPU`s RAM memory and executed from RAM memory. If additional program integrity is desired, or operation of the PLC without a battery is desired, an optional EEPROM or EPROM can be installed in a spare socket (labeled PROGRAM PROM) on the Model 311/313 backplane or in a socket on the model 331/341 CPU Module. EEPROMs can be written to and read from. EPROMs can be read when installed in the PLC; however, they must be written to using an external PROM programming device. Following is the procedure for adding or changing the EEPROM or EPROM. For clarity, the term PROM is used to refer to either an EEPROM or an EPROM. 1. Remove power from the system. 2. If 311/313  Remove all modules, including the power supply.  Remove the plastic cover. 3. If 331/341:  Remove CPU from backplane.  Remove front plate and bezel. Unsnap circuit board and remove from case. 4. If the socket is the type which has a screw near the top edge (some versions of 311/331), loosen screw at top of PROM socket (CCW twist;). 5. If present, remove old PROM from socket. Replace with or install new PROM. Orient the PROM so the end with a notch (the top of the prom) is toward the top edge of the backplane. Pin 1 of the prom is the first pin on the left as you move counter–clockwise from the notch. On the 311/331, correct installation orients the notch toward the screw.




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