To solve this problem it is necessary to apply the concepts related to thermal transfer given by the thermodynamic definition of heat as a function of mass, specific heat and temperature change.
Mathematically this is equivalent to
[tex]Q = mC_p \Delta T[/tex]
Where
m = mass
[tex]C_p =[/tex] Specific Heat
[tex]\Delta T =[/tex] Change at temperature
In mass terms (KJ / g) this can be expressed as
[tex]\frac{Q}{g} = \frac{C_p \Delta T}{m_{grams}}[/tex]
Our values are given as
[tex]\Delta T = 29.8-25.25 = 4.55\°C[/tex]
[tex]C_p = 31.71kJ/\°C[/tex]
Replacing,
[tex]\frac{Q}{m} = \frac{(31.71kJ/\°C) (4.55\°C)}{2.599g}[/tex]
[tex]\frac{Q}{m} =55.51kJ/g[/tex]
Therefore the heat of combustion per gram on the material is 55.51KJ/g
