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# Bias voltage is the voltage it takes to get the diode to start conducting. Below a certain voltage, the diode won't conduct current even in the forward direction. It is the voltage which allows the electrons and holes to overcome the depleted zone and meet with each other, creating current. Reverse Biased means that the positive end of the battery is connected with the n-type semiconductor and the negative end is connected with the p-type semiconductor. This sucks all the electrons from the n-type region and fills in all the holes in the p-type region, increasing the size of the depleted zone.  
 
# Bias voltage is the voltage it takes to get the diode to start conducting. Below a certain voltage, the diode won't conduct current even in the forward direction. It is the voltage which allows the electrons and holes to overcome the depleted zone and meet with each other, creating current. Reverse Biased means that the positive end of the battery is connected with the n-type semiconductor and the negative end is connected with the p-type semiconductor. This sucks all the electrons from the n-type region and fills in all the holes in the p-type region, increasing the size of the depleted zone.  
 
# Diode breakdown happens when a reverse biased diode is subjected to so much voltage that it conducts in the reverse direction. When a diode is reverse-biased past the breakdown voltage, it stays enters metastable state, in which any at free charge would start an avalanche and make the diode draw so much current that it may damage the diode.
 
# Diode breakdown happens when a reverse biased diode is subjected to so much voltage that it conducts in the reverse direction. When a diode is reverse-biased past the breakdown voltage, it stays enters metastable state, in which any at free charge would start an avalanche and make the diode draw so much current that it may damage the diode.
# If a resister is placed in the circuit, it prevents the current from getting too high and stops the diode from being fried.  To make an avalanche-like pulse, you would also a capacitor that would be connected in parallel to the diode. It serves as a temporary battery that supplies enough current to create an initial breakdown pulse, after which the capacitor is drained and the resister reduces the voltage below breakdown and the breakdown condition is no longer met and the avalanche is self quenched.  
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# If a resister is placed in the circuit, it prevents the current from getting too high and stops the diode from being fried.  To make an avalanche-like pulse, you would also a capacitor that would be connected in parallel to the diode. It serves as a temporary battery that supplies enough current to create an initial breakdown pulse, after which the capacitor is drained and the resister reduces the voltage below breakdown and the breakdown condition is no longer met and the avalanche is self-quenched.  
 
# A Photodiode is a diode that is especially sensitive to light. It is usually made with a clear glass or plastic case that allows light through to maximize the effect it has upon the diode.
 
# A Photodiode is a diode that is especially sensitive to light. It is usually made with a clear glass or plastic case that allows light through to maximize the effect it has upon the diode.
 
# An avalanche photodiode is a diode designed in such a way that it releases a pulse of electrons per photon instead of just one. In the process mentioned beforehand, the avalanche photodiode uses the energy from the photon to throw the photodiode off its metastable state and create a pulse.  
 
# An avalanche photodiode is a diode designed in such a way that it releases a pulse of electrons per photon instead of just one. In the process mentioned beforehand, the avalanche photodiode uses the energy from the photon to throw the photodiode off its metastable state and create a pulse.  
 
# Temperatures are caused by vibrations of atoms and a higher temperature would cause more random thermal fluctuations. Some of these thermal fluctuations have enough energy to throw the photodiode off its metastable state also, causing misfiring.
 
# Temperatures are caused by vibrations of atoms and a higher temperature would cause more random thermal fluctuations. Some of these thermal fluctuations have enough energy to throw the photodiode off its metastable state also, causing misfiring.
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