houlahound said:Unlike Ohmic resistors the resistance of a semiconductor decreases with temperature...or not.
Can a fragment chipped off a diode or some random IC be used to measure this with a multi meter??
Just what I was about to propose !houlahound said:So just get a diode connected to an ohm meter and dip it in say ice water, measure then boiling water measure??
The diode's V-I curve is temperature dependent. So the voltage varies if you change the current and also if you change the temperature. So the best arrangement for use as a thermometer would be to, say, fix current constant and measure the changes in V with temperature.houlahound said:So just get a diode connected to an ohm meter and dip it in say ice water, measure then boiling water measure??
houlahound said:I'm skeptical its that easy.
I don't know if a diode has a temp coefficient per we but will the differences in ihms even be noticeable on a hobby multimeter??
houlahound said:How do I measure it without getting it wet? Paint it in a sealant??
...and don`t forget that the diode has a non-linear V-I characteristics which means that you always have to discriminate between the STATIC (DC) and DYNAMIC (AC) resistance.houlahound said:Will try this when back at my man den next week and post the results.
Thanks.
Just says that some current will go through the water instead of through the diode, causing the meter to give a misleading reading.houlahound said:K, anyone want to explain what this leakage phenomena is, not something I have heard of.
A semiconductor is a material that has electrical conductivity between that of a conductor and an insulator. Examples of semiconductors include silicon, germanium, and gallium arsenide.
Measuring the resistance of a semiconductor is important because it can provide valuable information about the material's electrical properties, such as its conductivity and ability to conduct current. This information is crucial for understanding how a semiconductor can be used in electronic devices.
The materials needed for this experiment include a semiconductor sample, two metal probes, a power supply, and a multimeter. The multimeter is used to measure the resistance of the semiconductor sample.
To conduct the experiment, the semiconductor sample is connected to the power supply and the two metal probes are placed on either side of the sample. The multimeter is then used to measure the resistance between the two probes. The voltage and current can also be adjusted to calculate the resistance using Ohm's Law.
Potential sources of error in this experiment include variations in temperature, humidity, and the quality of the semiconductor sample. It is important to control these factors and ensure that the sample is clean and free from any impurities that could affect the resistance measurement.