Integrated circuit - P-N Junction, Transistors, Microchips | Britannica (original) (raw)
Also called:
microelectronic circuit, microchip, or chip
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A _p_-type or an _n_-type semiconductor is not very useful on its own. However, joining these opposite materials creates what is called a _p_-n junction. A _p_-n junction forms a barrier to conduction between the materials. Although the electrons in the _n_-type material are attracted to the holes in the _p_-type material, the electrons are not normally energetic enough to overcome the intervening barrier. However, if additional energy is provided to the electrons in the _n_-type material, they will be capable of crossing the barrier into the _p_-type material—and current will flow. This additional energy can be supplied by applying a positive voltage to the _p_-type material. The negatively charged electrons will then be highly attracted to the positive voltage across the junction.
A _p_-n junction that conducts electricity when energy is added to the n material is called forward-biased because the electrons move forward into the holes. If voltage is applied in the opposite direction—a positive voltage connected to the n side of the junction—no current will flow. The electrons in the n material will still be attracted to the positive voltage, but the voltage will now be on the same side of the barrier as the electrons. In this state a junction is said to be reverse-biased. Since _p_-n junctions conduct electricity in only one direction, they are a type of diode. Diodes are essential building blocks of semiconductor switches.
Field-effect transistors
Bringing a negative voltage close to the centre of a long strip of _n_-type material will repel nearby electrons in the material and thus form holes—that is, transform some of the strip in the middle to _p_-type material. This change in polarity using an electric field gives the field-effect transistor its name. While the voltage is being applied, there will exist two _p_-n junctions along the strip, from n to p and then from p back to n. One of the two junctions will always be reverse-biased. Since reverse-biased junctions cannot conduct, current cannot flow through the strip.
The field effect can be used to create a switch (transistor) to turn current off and on, simply by applying and removing a small voltage nearby in order to create or destroy reverse-biased diodes in the material. A transistor created by using the field effect is called a field-effect transistor (FET). The location where the voltage is applied is known as a gate. The gate is separated from the transistor strip by a thin layer of insulation to prevent it from short-circuiting the flow of electrons through the semiconductor from an input (source) electrode to an output (drain) electrode.
Similarly, a switch can be made by placing a positive gate voltage near a strip of _p_-type material. A positive voltage attracts electrons and thus forms a region of n within a strip of p. This again creates two _p_-n junctions, or diodes. As before, one of the diodes will always be reverse-biased and will stop current from flowing.
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FETs are good for building logic circuits because they require only a small current during switching. No current is required for holding the transistor in an on or off state; a voltage will maintain the state. This type of switching helps preserve battery life. A FET is called unipolar (from “one polarity”) because the main conduction method is either holes or electrons, not both.
Enhancement-mode FETs
There are two basic types of FETs. The type described previously is a depletion-mode FET, since a region is depleted of its natural charge. The field effect can also be used to create what is called an enhancement-mode FET by enhancing a region to appear similar to its surrounding regions.
depletion mode versus enhancement mode MOSFETs In depletion mode metal-oxide-semiconductor field-effect transistors (MOSFETs), a secondary voltage is applied to deplete the region under the gate of charge carriers, thereby pinching off the current. In enhancement mode MOSFETs, a secondary voltage is used to enhance charge carriers beneath the gate, thereby allowing current to flow. Whereas the first type has to deplete a cross section of the semiconductor of carriers in order to switch the circuit's status, the second type only has to enhance a small region near the gate. Thus, enhancement mode MOSFETS are easier to control and can switch states faster than depletion mode MOSFETS.
An _n_-type enhancement-mode FET is made from two regions of _n_-type material separated by a small region of p. As this FET naturally contains two _p_-n junctions—two diodes—it is normally switched off. However, when a positive voltage is placed on the gate, the voltage attracts electrons and creates _n_-type material in the middle region, filling the gap that was previously _p_-type material. The gate voltage thus creates a continuous region of n across the entire strip, allowing current to flow from one side to the other. This turns the transistor on. Similarly, a _p_-type enhancement-mode FET can be made from two regions of _p_-type material separated by a small region of n. The gate voltage required for turning on this transistor is negative. Enhancement-mode FETs switch faster than depletion-mode FETs because they require a change only near the surface under the gate, rather than all the way through the material.
Complementary metal-oxide semiconductors
CMOS A complementary metal-oxide semiconductor (CMOS) consists of a pair of semiconductors connected to a common secondary voltage such that they operate in opposite (complementary) fashion. Thus, when one transistor is turned on, the other is turned off, and vice versa.
Recall that placing a positive voltage at the gate of an _n_-type enhanced-mode FET will turn the switch on. Placing the same voltage at the gate of a _p_-type enhanced-mode FET will turn the switch off. Likewise, placing a negative voltage at the gate will turn the _n_-type off and the _p_-type on. These FETs always respond in opposite, or complementary, fashion to a given gate voltage. Thus, if the gates of an _n_-type and a _p_-type FET are connected any voltage applied to the common gate will operate the complementary pair, turning one on and leaving the other off. A semiconductor that pairs _n_- and _p_-type transistors this way is called a complementary metal-oxide semiconductor (CMOS). Because complementary transistor pairs can quickly switch between two logic states, CMOSs are very useful in logic circuits. In particular, because only one circuit is on at any time, CMOSs require less power and are often used for battery-powered devices, such as in digital cameras, and for the special memory that holds the date, time, and system parameters in personal computers.