Semiconductor ElectronicsMind Map

Semiconductor basics begin with energy band theory. In solids, closely spaced atomic energy levels form bands: the valence band contains bound electrons, while the conduction band contains mobile electrons that conduct current. The forbidden energy gap between them decides electrical behavior. Conductors have overlapping bands or almost no gap, so electrons move easily. Insulators have a large gap, so electrons cannot easily reach the conduction band. Semiconductors have a small gap, so heat or light can create charge carriers. Unlike metals, semiconductor resistance decreases with temperature because more electron-hole pairs are generated. This topic also introduces electrons and holes as charge carriers, which are essential for understanding doping, PN junctions and diodes.

An intrinsic semiconductor is a pure semiconductor such as silicon or germanium in which charge carriers are produced only by thermal generation. Hence the number of electrons equals the number of holes. Its conductivity is limited at room temperature. To increase and control conductivity, a small amount of impurity is added; this process is called doping. Pentavalent impurities like phosphorus donate extra electrons and form n-type semiconductors, where electrons are majority carriers and holes are minority carriers. Trivalent impurities like boron accept electrons and create holes, forming p-type semiconductors. Doping does not make the material electrically charged overall; it only changes carrier concentration. Understanding majority and minority carriers is essential for PN junction behavior.

A PN junction is formed when p-type and n-type semiconductors are joined. Electrons from the n-side diffuse into the p-side and recombine with holes, while holes from the p-side diffuse into the n-side and recombine with electrons. This leaves behind immobile ionized donors and acceptors near the junction, creating a depletion region with almost no mobile carriers. The resulting electric field produces a barrier potential that opposes further diffusion. In forward bias, the p-side is connected to positive terminal and n-side to negative terminal, reducing the barrier and allowing large current. In reverse bias, the barrier widens and only a small reverse saturation current flows until breakdown.

A PN junction diode is a two-terminal semiconductor device that conducts mainly in forward bias and blocks current in reverse bias. This unidirectional property makes it useful as a rectifier, a device that converts alternating current into pulsating direct current. In a half-wave rectifier, one diode conducts during only one half cycle of AC, so the output contains separated pulses. In a full-wave rectifier, two diodes with a centre-tapped transformer or a bridge arrangement conduct during alternate half cycles, producing output in the same direction for both halves. Diode characteristics, threshold voltage, rectified waveforms and circuit connections are important for NEET. Diodes are also used in protection, switching and signal detection circuits.

A Zener diode is a specially designed heavily doped PN junction diode that operates safely in reverse breakdown. In reverse bias, when the applied voltage reaches the Zener voltage, a strong electric field causes a sudden increase in reverse current while the voltage across the diode remains nearly constant. This property makes it useful as a voltage regulator. In a regulator circuit, the Zener diode is connected in reverse bias parallel to the load with a series resistor. When input voltage or load current changes, the Zener current adjusts so that load voltage remains approximately equal to Zener voltage. For NEET, the key ideas are reverse bias operation, sharp breakdown, constant voltage and correct circuit connection.

Logic gates are electronic circuits that perform Boolean operations on binary inputs. Digital systems use two states: 0 for low voltage and 1 for high voltage. The basic gates are OR, AND and NOT. OR gives output 1 if at least one input is 1; AND gives output 1 only when all inputs are 1; NOT inverts the input. NAND and NOR are called universal gates because any logic circuit can be built using only NAND gates or only NOR gates. XOR gives output 1 when inputs are different. NEET questions usually test symbols, Boolean expressions, truth tables and identification of universal gates. Understanding gates as decision rules makes the topic fast and scoring.