Explain the design,working,uses,and benefits of a light-emitting diode $(LED)$.
(N/A) Design: An $LED$ is a heavily doped $p-n$ junction diode. It is encapsulated in a transparent cover so that the emitted light can escape. It is operated under forward bias.
Working: When the diode is forward-biased,electrons are injected from the $n$-region to the $p$-region,and holes are injected from the $p$-region to the $n$-region. Near the junction boundary,the concentration of these minority carriers increases. These excess minority carriers recombine with majority carriers near the junction. During this recombination,energy is released in the form of photons. The energy of the emitted photons is approximately equal to or slightly less than the band gap energy $(E_g)$. As forward current increases,the intensity of light increases,reaches a maximum,and then decreases due to heating effects.
Uses: $LED$s are used in remote controls,optical communication,traffic signals,decorative lighting,and displays.
Benefits: $LED$s have low operational voltage,fast action,no warm-up time required,long life,ruggedness,and they are available in different colors.
Working: When the diode is forward-biased,electrons are injected from the $n$-region to the $p$-region,and holes are injected from the $p$-region to the $n$-region. Near the junction boundary,the concentration of these minority carriers increases. These excess minority carriers recombine with majority carriers near the junction. During this recombination,energy is released in the form of photons. The energy of the emitted photons is approximately equal to or slightly less than the band gap energy $(E_g)$. As forward current increases,the intensity of light increases,reaches a maximum,and then decreases due to heating effects.
Uses: $LED$s are used in remote controls,optical communication,traffic signals,decorative lighting,and displays.
Benefits: $LED$s have low operational voltage,fast action,no warm-up time required,long life,ruggedness,and they are available in different colors.
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The current in the forward bias is known to be more $(\sim mA)$ than the current in the reverse bias $(\sim \mu A)$. What is the reason then to operate the photodiodes in reverse bias?
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View SolutionFor an $LED$ to emit light in the visible region of the electromagnetic spectrum,it can have an energy band gap in the range of (Planck's constant,$h = 6.6 \times 10^{-34} \ J s$ and speed of light,$c = 3 \times 10^8 \ m s^{-1}$ in vacuum).
$A$ $p-n$ photodiode is manufactured from a semiconductor with a band gap of $3.1 \,eV$. Which of the following wavelengths can be detected by it?
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View SolutionState the band gap of the semiconductor used in the making of $LED$.
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View SolutionThe $I-V$ characteristics of a photodiode for different illumination intensities $I_1, I_2, I_3$ and $I_4$ are shown in the figure. Which of the following represents the maximum intensity?
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