Ask Question
20 June, 14:16

An electronic circuit element consists of 23 mg of silicon. An electric current through the circuit adds heat at a rate of 7.4 x 10-3 J/s. At what rate does the temperature of the circuit element increase? Assume that heat does not transfer from the circuit element to the environment. The specific heat capacity of silicon is.

+4
Answers (1)
  1. 20 June, 14:52
    0
    Given that all the heat is absorbed by the silicon element, the calculation is:

    Heat = m * specific heat * ΔT

    Heat rate = heat / time = m * specif heat * ΔT / time

    Where ΔT / time = temperature change rate, which is what you want to calculate

    => ΔT / time = heat rate / (m*specific heat)

    You have:

    heat rate = 7.4 * 10 ^-3 J/s

    m = 23 mg = 23 * 10^ - 3 g

    Specific heat = 0.7 J / (g * °C), taken from internet because you forgo to include the information.

    => ΔT / t = [7.4 * 10^ - 3 J/s ] / [ 23 * 10^ - 3 g * 0.7 J / (g*°C) ]

    => ΔT / t = 0.46 °C / s

    Answer: 0.46°C / s
Know the Answer?
Not Sure About the Answer?
Get an answer to your question ✅ “An electronic circuit element consists of 23 mg of silicon. An electric current through the circuit adds heat at a rate of 7.4 x 10-3 J/s. ...” in 📙 Chemistry if there is no answer or all answers are wrong, use a search bar and try to find the answer among similar questions.
Search for Other Answers