Internal Energy and Specific Heat Capacity

Internal energy is the sum of the kinetic and potential energies of the particles within a substance. It is directly related to the temperature of a substance, as an increase in temperature leads to an increase in the kinetic energy of the particles, thus increasing the internal energy.

Internal energy is the energy stored in the bonds between atoms, and it has no relationship with the temperature of a substance.

Internal energy is the energy that a substance absorbs from its surroundings, and it is not affected by the temperature.

Internal energy is the energy that a substance releases to its surroundings, and it decreases as the temperature increases.

50.75°C

15.40°C

40.60°C

32.22°C

10.75 J/g°C

2.50 J/g°C

4.18 J/g°C

6.32 J/g°C

Cooking, heating and cooling systems, insulation

Skiing, snowboarding, ice skating

Swimming, cycling, running

Reading, writing, drawing

The kinetic theory of gas explains that gas particles are in constant motion and the internal energy of a gas is related to the kinetic energy of its particles.

The kinetic theory of gas explains that gas particles are in constant motion and the internal energy of a gas is related to the potential energy of its particles.

The kinetic theory of gas explains that gas particles are in constant motion and the internal energy of a gas is not related to the kinetic energy of its particles.

The kinetic theory of gas explains that gas particles are at rest and the internal energy is related to the potential energy of its particles.

Q = (3 kg)(390 J/kg°C)(80°C - 20°C) = 54,600 J

Q = (3 kg)(390 J/kg°C)(80°C - 20°C) = 5,460 J

Q = (3 kg)(390 J/kg°C)(80°C + 20°C) = 54,600 J

Q = (3 kg)(390 J/kg°C)(80°C - 20°C) = 15,600 J

It affects the substance's ability to store and release heat.

It causes the substance to release heat but not store it.

It only affects the substance's ability to store heat, not release it.

It has no effect on the substance's ability to store and release heat.

Color, density, and volume

Pressure, state of matter, and electrical conductivity

Mass, temperature, and molecular structure

Atomic number, boiling point, and solubility