GCSE Physics - Internal Energy and Specific Heat Capacity #28

Cognito

6 Oct 201904:36

Summary

TLDRThis video explores the relationship between an object's internal energy and temperature through the concept of specific heat capacity. It explains that internal energy consists of potential and kinetic energy, with the latter being crucial for temperature changes. The script introduces specific heat capacity as the energy required to raise a substance's temperature by one degree Celsius and demonstrates its application with a practical example. The video concludes with a calculation to find the final temperature of water after energy transfer, highlighting the importance of insulation in real-life experiments.

Takeaways

🔥 Internal energy is the total energy stored by the particles in a substance or system, often divided into potential and kinetic energy.
🌡 Kinetic energy, which is related to the movement of particles, is the key component affecting temperature when a substance is heated.
🌡 Temperature is a measure of the average internal energy of a substance, with higher internal energy correlating to higher temperature.
🔄 Materials vary in the amount of energy required to change their temperature, which is described by specific heat capacity.
💧 Water has a high specific heat capacity, requiring 4,200 joules to raise the temperature of 1 kg by 1 degree Celsius.
🌀 Mercury has a much lower specific heat capacity, needing only 139 joules to heat 1 kg by 1 degree Celsius.
⚖ The specific heat capacity can be defined as the energy needed to raise the temperature of 1 kg of a substance by 1 degree or the energy released when it cools.
📚 The change in internal energy can be calculated using the formula: ΔE = m * c * ΔT, where ΔE is the change in internal energy, m is the mass, c is the specific heat capacity, and ΔT is the change in temperature.
📈 An example in the script calculates the final temperature of 800 grams of water after 20 kilojoules of energy transfer, using the specific heat capacity of water.
🔢 The calculation involves converting units to kilograms and joules, and then applying the formula to find a temperature change of 5.95 degrees Celsius.
⚠ Real-world energy transfer may not result in the exact temperature increase due to energy loss to the surroundings, especially in an open system without insulation.

Q & A

What is internal energy?
-Internal energy is the total energy stored by the particles making up a substance or system.
How is internal energy divided?
-Internal energy is often considered to be made up of two parts: potential energy stores and kinetic energy stores.
Which part of internal energy is related to temperature?
-The kinetic energy store is related to temperature, as it involves the movement energy of the particles.
What happens when a substance is heated?
-When a substance is heated, energy is transferred to the kinetic energy store of its particles, increasing their internal energy and thereby raising the temperature.
What is specific heat capacity?
-Specific heat capacity is the amount of energy needed to raise the temperature of one kilogram of a substance by one degree Celsius.
How does the specific heat capacity of water compare to mercury?
-Water has a specific heat capacity of 4200 joules per kilogram per degree Celsius, whereas mercury requires only 139 joules per kilogram per degree Celsius.
What is the formula for calculating the change in internal energy?
-The change in internal energy is equal to the mass times the specific heat capacity of the substance times the change in temperature.
How can you find the change in temperature from the change in internal energy?
-To find the change in temperature, divide the change in internal energy by the product of mass and specific heat capacity.
What is the specific heat capacity of water?
-The specific heat capacity of water is 4200 joules per kilogram per degree Celsius.
What would be the final temperature of 800 grams of water initially at 20 degrees Celsius after 20 kilojoules of energy has been transferred to it?
-The final temperature would be 25.95 degrees Celsius, or 26.0 degrees if rounded to three significant figures.