Answer:
[tex]m_{KBr}=6.030gKBr[/tex]
Explanation:
Hello.
In this case, since the normal boiling point of X is 117.80 °C, the boiling point elevation constant is 1.48 °C*kg*mol⁻¹, the mass of X is 100 g and the boiling point of the mixture of X and KBr boils at 119.3 °C, we can use the following formula:
[tex](T_b-T_b_0)=i*m*K_b[/tex]
Whereas the Van't Hoff factor of KBr is 2 as it dissociates into potassium cations and bromide ions; it means that we can compute the molality of the solution:
[tex]m=\frac{T_b-T_b_0}{i*K_b}=\frac{(119.3-117.8)\°C}{2*1.48\°C*kg*mol^{-1}}\\ \\m=0.507mol/kg[/tex]
Next, given the mass of solventin kg (0.1 kg from 100 g), we compute the moles KBr:
[tex]n_{KBr}=0.507mol/kg*0.1kg=0.0507mol[/tex]
Finally, considering the molar mass of KBr (119 g/mol) we compute the mass that was dissolved:
[tex]m_{KBr}=0.0507mol*\frac{119g}{1mol} \\\\m_{KBr}=6.030gKBr[/tex]
Best regards.
