solar cell

solar cell

A device by which incident solar radiation is converted directly into electrical energy. It is a semiconductor device that is identical in principle to the photovoltaic detector and has a p-n junction with a large surface area. Solar radiation falling on or near the junction produces an external voltage. A variety of different semiconductors, dopants, and fabrication techniques have been used to increase the conversion efficiency and the power delivered. The conversion efficiency can exceed 30%.

Solar cells form the main power supply in satellites, space stations, and short-range planetary probes. The cells are arranged on flat solar panels outside the craft to receive the maximum amount of radiation from the Sun. On probes traveling beyond Mars the radiation flux is insufficient to power the instruments: the solar constant at Jupiter's orbit is only about 4% of the value at the Earth's orbit. Power must then be obtained from other sources, such as thermoelectric generators.

Collins Dictionary of Astronomy © Market House Books Ltd, 2006

solar cell

[′sō·lər ′sel]

(electronics)

A pn-junction device which converts the radiant energy of sunlight directly and efficiently into electrical energy.

McGraw-Hill Dictionary of Scientific & Technical Terms, 6E, Copyright © 2003 by The McGraw-Hill Companies, Inc.

Solar cell

A semiconductor electrical junction device which absorbs and converts the radiant energy of sunlight directly and efficiently into electrical energy. Solar cells may be used individually as light detectors, for example in cameras, or connected in series and parallel to obtain the required values of current and voltage for electric power generation.

Most solar cells are made from single-crystal silicon and have been very expensive for generating electricity, but have found application in space satellites and remote areas where low-cost conventional power sources have been unavailable.

The conversion of sunlight into electrical energy in a solar cell involves three major processes: absorption of the sunlight in the semiconductor material; generation and separation of free positive and negative charges to different regions of the solar cell, creating a voltage in the solar cell; and transfer of these separated charges through electrical terminals to the outside application in the form of electric current.

When light is absorbed in the semiconductor, a negatively charged electron and positively charged hole are created. The heart of the solar cell is the electrical junction which separates these electrons and holes from one another after they are created by the light. An electrical junction may be formed by the contact of: a metal to a semiconductor (this junction is called a Schottky barrier); a liquid to a semiconductor to form a photo-electrochemical cell; or two semiconductor regions (called a pn junction).

The fundamental principles of the electrical junction can be illustrated with the silicon pn junction. Pure silicon to which a trace amount of a group V element (in the periodic table) such as phosphorus has been added is an n-type semiconductor, where electric current is carried by free electrons. Each phosphorus atom contributes one free electron, leaving behind the phosphorus atom bound to the crystal structure with a unit positive charge. Similarly, pure silicon to which a trace amount of a group III element such as boron has been added is a p-type semiconductor, where the electric current is carried by free holes. The interface between the p- and n-type silicon is called the pn junction. The fixed charges at the interface due to the bound boron and phosphorus atoms create a permanent dipole charge layer with a high electric field. When photons of light energy from the Sun produce electron-hole pairs near the junction, the built-in electric field forces the holes to the p side and the electrons to the n side. This displacement of free charges results in a voltage difference between the two regions of the crystal. When a load is connected at the terminals, an electron current flows and useful electrical power is available at the load. See Semiconductor, Solar energy

McGraw-Hill Concise Encyclopedia of Engineering. © 2002 by The McGraw-Hill Companies, Inc.

photodiode

A light sensor (photodetector) that allows current to flow in one direction from one side to the other when it absorbs photons (light). The more light, the more current. Used to detect light in camera sensors, optical fibers and other light-sensitive applications, a photodiode is the opposite of a light emitting diode (see LED). Photodiodes detect light and let electricity flow; LEDs receive electricity and emit light.

Solar Cells Are Photodiodes
Solar cells are photodiodes that are chemically treated (doped) differently than the photodiode used as a switch or relay. When solar cells are struck by light, their silicon material is excited to a state where a small electrical current is generated. Many arrays of solar cell photodiodes are required to power a house. See photocell and phototransistor.

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photovoltaic

The generation of voltage by a material that is exposed to light in the visible and invisible ranges. See photoelectric and photovoltaic cell.

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