Physics - semiconductor diode.

In summary, the problem at hand is to set up an experiment to investigate the effect of temperature on the breakdown voltage of a semiconductor diode. The temperature range needed to be achieved is -70 degrees C to 150 degrees C. Suggestions for achieving this temperature range include using dry ice, liquid nitrogen, or a kitchen oven. To measure the breakdown voltage, a circuit can be set up with a current limiting resistor in series with the diode. Monitoring the voltage drop across the resistor can indicate when breakdown occurs. It is important to avoid large currents during the test to prevent damage to the diode.
  • #1
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The problem is an experiment has to be set up to investigate how the breakdown voltage (which occurs by a large reverse potential difference is applied to the diode, and the diode then passes a large current) of a semiconductor diode is affected by temperature.


My problem is how can I vary the temp. of the diode in the range of minus 70 degrees C to 150 degrees C, whihc is what the question asks for,

I think I can get a range of about -10 celcius to 70 degrees , but I also want to ask whether it is safe to submerge the diode in hot water (which will be heated by a bunsen burner)?

Also how can I set up a circuit so that the breakdown Voltage is calculated BUT also avoid large currents (which would cause damage to the diode when breakdown occurs) <- this is probably the most important bit.
#


THANKS to anyone with any ideas and suggestions!
 
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  • #2
Dry ice can attain approx (-60 degC). Liquid nitrogen can attain approx (-200 degC). A standard kitchen oven can be preheated (and then the heat turned off) to almost any temperature up to (+200 degC).

For the diode "reverse-bias" voltage breakdown test, place the diode in series with a current limiting resistor "R". During the test, monitor the voltage drop across R. Before breakdown, very little voltage will drop across "R" (diode limits current). After breakdown, you will see a noticeable change, and R will limit the current thru the diode.


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  • #3
Thanks very much for your help.
 
  • #4
"During the test, monitor the voltage drop across R."

by voltage drop, do you mean the voltage across R gets more negative, as the breakdown voltage is approached?
 
  • #5
The voltage drop magnitude across R will increase when breakdown occurs since more current will flow through R. Whether you measure it positive or negative depends on how you've connected your meter. Presumably you'll connect your meter with the (+) lead on the terminal of R closest to the (+) voltage source. In that case, the reading will change from near 0 before breakdown to a larger (+) reading after breakdown.
 

What is a semiconductor diode?

A semiconductor diode is a device made from a material such as silicon or germanium that has both conductive and non-conductive properties. It allows current to flow in only one direction, making it useful for controlling the flow of electricity in electronic circuits.

How does a semiconductor diode work?

A semiconductor diode works by creating a junction between two different types of semiconductor materials. One side is doped with an excess of electrons, making it negatively charged, while the other side is doped with a lack of electrons, making it positively charged. When a voltage is applied, the electrons flow from the negative side to the positive side, creating a flow of current.

What are the applications of semiconductor diodes?

Semiconductor diodes have a wide range of applications in electronics. They are commonly used in rectifier circuits to convert AC power to DC power, in LED lights for illumination, and in solar cells to convert sunlight into electricity. They are also used in electronic devices such as computers, televisions, and smartphones.

What are the different types of semiconductor diodes?

There are several types of semiconductor diodes, each with their own unique properties and applications. Some common types include the p-n junction diode, Zener diode, Schottky diode, and photodiode. Each type has a specific structure and function that make it suitable for different electronic applications.

What are the advantages of using semiconductor diodes?

Semiconductor diodes offer several advantages in electronic circuits. They are small in size, have high reliability, and can operate at high speeds. They also have low power consumption, making them ideal for use in portable electronic devices. Additionally, semiconductor diodes have a long lifespan and are relatively inexpensive to produce.

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