22. The First Law of Thermodynamics

A gas in a cylinder held at a constant pressure 1.80×10⁵ Pa expands from a volume of 1.2 m³ to 1.6 m³. The internal energy of the gas decreases from 4.40×10⁵ J to 3×10⁵ J. How much heat was transferred to the gas?

The internal energy of a system decreases by 500 J, and 230 J of work is done on the system. What is the heat transfer into or out of this system?

(II) How many joules and kilocalories are generated when the brakes are used to bring a 1200-kg car to rest from a speed of 95 km/h?

(II) A 64-kg ice skater moving at 8.5 m/s glides to a stop. Assuming the ice is at 0°C and that 50% of the heat generated by friction is absorbed by the ice, how much ice melts?

A scuba diver releases a 3.60-cm-diameter (spherical) bubble of air from a depth of 14.0 m. Assume the temperature is constant at 298 K, and that the air behaves as an ideal gas. (a) How large is the bubble when it reaches the surface? Take the density of water to be 1000 kg/m³.

A scuba diver releases a 3.60-cm-diameter (spherical) bubble of air from a depth of 14.0 m. Assume the temperature is constant at 298 K, and that the air behaves as an ideal gas. (b) Sketch a PV diagram for the process. Take the density of water to be 1000 kg/m³.

A scuba diver releases a 3.60-cm-diameter (spherical) bubble of air from a depth of 14.0 m. Assume the temperature is constant at 298 K, and that the air behaves as an ideal gas. (c) Apply the first law of thermodynamics to the bubble, and find the work done by the air in rising to the surface, the change in its internal energy, and the heat added or removed from the air in the bubble as it rises. Take the density of water to be 1000 kg/m³.

(I) An ideal gas expands isothermally, performing 4.30 x 10 ³ J of work in the process. Calculate

(b) the heat absorbed during this expansion.

Two cylinders each contain 0.10 mol of a diatomic gas at 300 K and a pressure of 3.0 atm. Cylinder A expands isothermally and cylinder B expands adiabatically until the pressure of each is 1.0 atm.

a. What are the final temperature and volume of each?

(II) How much work is done by a pump to slowly compress, isothermally, 3.20 L of nitrogen at 0°C and 1.00 atm to 1.80 L at 0°C?

A heat engine takes a diatomic gas around the cycle shown in Fig. 20–23.

(c) Calculate the heat input into the gas during the constant volume process from points b to c.

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