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1. Definition
A PN junction is a microstructure formed at the interface where a P-type semiconductor and an N-type semiconductor are in close contact. It exhibits unidirectional conductivity and serves as the core foundation for photoelectric conversion in image sensors.
(Image source: https://en.wikipedia.org/wiki/P%E2%80%93n_junction#/media/File:PN_diode_with_electrical_symbol.svg)
2. Materials
The formation of a PN junction relies on two semiconductor materials with different doping types. By doping with specific impurity elements, the conductivity of an intrinsic semiconductor (pure silicon crystal) can increase by millions of times, forming two types of extrinsic semiconductors:
2.1 P-type Semiconductor (Positive-type, Hole-type)
2.2 N-type Semiconductor (Negative-type, Electron-type)
Core Concept Notes:
3. Formation
The formation of a PN junction begins with the diffusion of majority carriers driven by the concentration gradient. When P-type and N-type semiconductors come into contact, free holes in the P-region and free electrons in the N-region diffuse into the opposite region and recombine. Subsequently, positively charged ionized donors are left at the boundary of the N-region, and negatively charged ionized acceptors are left at the boundary of the P-region, thereby forming a built-in electric field (space charge region) directed from the N-region to the P-region at the interface. The drift motion generated by this electric field prevents further diffusion of majority carriers. Ultimately, under thermal equilibrium, the diffusion current of majority carriers and the drift current of minority carriers reach a dynamic balance, forming a stable PN junction.
4. Operating Principle
An external voltage applied to a PN junction disrupts the original dynamic balance, causing changes in its space charge region and thereby exhibiting unidirectional conductivity:
The external electric field opposes the built-in electric field, weakening the built-in electric field. The space charge region narrows, majority carriers resume diffusion and form a large current, and the PN junction exhibits a low-resistance conducting state.
The external electric field aligns with the built-in electric field, strengthening the built-in electric field. The space charge region widens, the diffusion of majority carriers is completely blocked, and only an extremely weak drift current of minority carriers exists, causing the PN junction to exhibit a high-resistance cut-off state.
5. Application: Image Sensors
The core component of image sensors (such as CMOS) is the silicon photodiode, which is essentially a PN junction operating in a reverse bias (cut-off) state, utilizing the photovoltaic effect to convert optical signals into electrical signals. Its photosensitive mechanism is divided into the following two scenarios:
Core Reason for Choosing Reverse Bias: It is to significantly widen the space charge region and strengthen the built-in electric field, thereby allowing more photons to participate in the highly efficient “direct drift” process. This prevents charge recombination losses while significantly improving the sensor's response speed and suppressing background noise (dark current).