The temperature of 500 g of water decreases by ΔT °C when placed in a fridge for 10 minutes. This container of water is then removed and a second container of mass 250 g and temperature 25 °C is placed in the same fridge for 20 minutes.
Assume that the containers holding the water are identical and do not emit or absorb energy. The specific heat capacity of water is 4200 J kg−1 K−1.
What is the final temperature of the second container of water after 20 minutes?
An engine goes through 6000 cycles every minute. To maintain a constant working temperature, 152 J of energy must be removed by a coolant during each complete cycle of the engine. The temperature of the coolant rises by 20 °C as it passes through the engine.
The specific heat capacity of the coolant is 3.8 × 103 J kg−1 K−1 and the density is 1000 kg m−3.
What is the volume of the coolant that flows through the engine in one second?
A glass beaker of water contains an immersion heater completely submerged by the water and is placed on the right-hand side of a two-pan balance. The heater boils the water at 100 °C and is connected to a kWh meter. When the water starts to boil standard masses are added to the left-hand side of the balance so it is in equilibrium with the water. At this moment the reading on the meter is 11.3 kWh.
A 400 g mass is then added to the left-hand side of the balance, causing it to tilt. As the water boils off the right pan rises until it is once again in equilibrium. When this happens the new reading on the meter is 11.5 kWh.
What is the specific latent heat of vapourisation of the steam if the heater is 50% efficient?
A spring in a ball point pen has a mass of 0.10 g and a specific heat capacity of 400 J kg−1 K−1 and a spring constant k = 200 N m−1. To open or close the nib of the pen the spring is compressed by 8 mm. Upon release 5% of the elastic potential energy stored is converted into heat energy in the spring.
How many times must the spring be compressed and released to cause the temperature of the pen to increase by 2 °C?
An ice cube of mass mi and temperature −Ti is dropped into a glass of water of mass mw and temperature Tw. The specific heat capacity of ice is ci and the specific latent heat of fusion of ice is Li. The specific heat capacity of water is cw.
Two bodies of equal mass A and B are brought into thermal contact. Object A has a temperature of 0 °C and object B has a temperature of 100 °C. Object A has a specific heat capacity greater than object B. No other exchanges of heat take place.