Select True or False from the pull down menus for the following statements.

During fusion (melting), no heat has to be added to make the phase change under constant pressure.

A zero slope in the heating and cooling curve indicates that a phase change is taking place.

Heat is the same as temperature. Temperature is a measure of average kinetic energy.

The amount of heat absorbed during melting is equal to the amount of heat released during freezing.

A coin dealer, offered a rare silver coin, suspected that it might be a counterfeit nickel copy. The dealer heated the coin, which weighed 15.5 g to 100°C in boiling water and then dropped the hot coin into 27.0 g of water at T = 15.5°C in an insulated coffee-cup, and measured the rise in temperature. If the coin was really made of silver, what would the final temperature of the water be (in °C) ? (for nickel, s = 0.445 J/g°C; for silver, s = 0.233 J/g°C)

Question

Chemistry

Immanuel Stephens

21 December, 18:29

Select True or False from the pull down menus for the following statements.

During fusion (melting), no heat has to be added to make the phase change under constant pressure.

A zero slope in the heating and cooling curve indicates that a phase change is taking place.

Heat is the same as temperature. Temperature is a measure of average kinetic energy.

The amount of heat absorbed during melting is equal to the amount of heat released during freezing.

A coin dealer, offered a rare silver coin, suspected that it might be a counterfeit nickel copy. The dealer heated the coin, which weighed 15.5 g to 100°C in boiling water and then dropped the hot coin into 27.0 g of water at T = 15.5°C in an insulated coffee-cup, and measured the rise in temperature. If the coin was really made of silver, what would the final temperature of the water be (in °C) ? (for nickel, s = 0.445 J/g°C; for silver, s = 0.233 J/g°C)

+4

Answers (1)

Know the Answer?

Brodie Fletcher · Answer 1

First question: 1 - False, 2 - True, 3 - False, 4 - Tue, 5 - True.

Second question: 12.7 ºC

Explanation:

First question:

1 - When a phase change for a pure substance is taking place under constant pressure, the temperature remains constant, and there's no sensitive heat flowing, but there's latent heat flow, which must be added to separate the molecules and to increase the kinetic energy.

2 - When observed the heating and the cooling curve, at the phase change, there is no change in temperature, so it must be a horizontal line, which has a slope equal to 0.

3 - Heat is the energy that is transferred by the substances or bodies because of a difference in temperature. The temperature is the measure of average kinetic energy in the molecules, so they are different.

4 - As explained above, it's true, that's the definition of temperature.

5 - Melting and freezing are the opposite processes and they occur at the same temperature. The difference is that for melting, the substance is absorbing heat, and for freezing it is losing heat, but the heat amount is the same for both process and is calculated by Q = ±m*L, where Q is the heat, m the mass, L the heat capacity, and the signal ± indicates if the substance is absorbing (+) or losing (-) heat.

Second question:

For the conservation of energy, the total amount of heat must be 0. The coin is losing heat, so it must be negative. The water is gaining heat, so it must be positive:

Qw - Qc = 0

Q = m*s*ΔT, where Q is the heat, m is the mass, s is the specif heat, and ΔT the temperature variation (final - initial). Qw is from water and Qc for the coin. The specif heat from the water is 4.184 J/gºC. At the thermal equilibrium, the final temperature must be equal for both.

mw*sw*ΔTw = mc*sc*ΔTc, if the coin is pure silver, sc = 0.233 J/gºC

27.0*4.184 * (T - 15.5) = 15.5*0.233 * (T - 100)

112.968 * (T - 15.5) = 3.6115 * (T - 100)

112.968T - 1751.004 = 3.6115T - 361.15

109.3565T = 1389.854

T = 1389.854/109.3565

T = 12.7ºC

So, the final water temperature would be 12.7ºC, which is impossible because it needs to increase. So the coin is not silver pure.