Answer:
The specific heat of the metal is 0.212 J/(g°C).
Explanation:
We can calculate the specific heat of the metal by the following equilibrium:
[tex] q_{a} = -q_{b} [/tex]
[tex] m_{a}C_{a}\Delta T_{a} = -m_{b}C_{b}\Delta T_{b} [/tex]
[tex]m_{a}C_{a}(T_{f_{a}} - T_{i_{a}}) = -m_{b}C_{b}(T_{f_{b}} - T_{i_{b}})[/tex]
In the above equation, we have that the heat loses by the metal (b) is gained by the water (a).
[tex]m_{a}[/tex]: is the water's mass = 72.0 g
[tex]C_{a}[/tex]: is the specific heat of water = 4.184 J/(g°C)
[tex]T_{i_{a}}[/tex]: is the initial temperature of the water = 19.2 °C
[tex]T_{f_{a}}[/tex]: is the final temperature of the water = 25.5 °C
[tex]m_{b}[/tex]: is the metal's mass = 141 g
[tex]C_{b}[/tex]: is the specific heat of metal =?
[tex]T_{i_{b}}[/tex]: is the initial temperature of the metal = 89.0 °C
[tex]T_{f_{b}}[/tex]: is the final temperature of the water = 25.5 °C
[tex]m_{a}C_{a}(T_{f_{a}} - T_{i_{a}}) = -m_{b}C_{b}(T_{f_{b}} - T_{i_{b}})[/tex]
[tex]72.0 g*4.184 J/(g^{\circ} C)*(25.5 ^{\circ} C - 19.2 ^{\circ} C) = -141 g*C_{b}*(25.5 ^{\circ} C - 89.0 ^{\circ} C)[/tex]
[tex] C_{b} = -\frac{72.0 g*4.184 J/(g^{\circ} C)(25.5 ^{\circ} C - 19.2 ^{\circ} C)}{141 g(25.5 ^{\circ} C - 89.0 ^{\circ} C)} = 0.212 J/(g^{\circ} C) [/tex]
Therefore, the specific heat of the metal is 0.212 J/(g°C).
I hope it helps you!
