Answer:
The emf and internal resistance of the battery are 9 volt and 2.04 Ω
Explanation:
Given that,
First resistor[tex]R = 100\ \Omega[/tex]
Power[tex]P = 0.794\ W[/tex]
Second resistor[tex]R=200\ \Omega[/tex]
Power[tex]P=0.401\ W[/tex]
We need to calculate the emf and internal resistance
Using formula of emf
[tex]P=\dfrac{e^2}{R+r}[/tex]
For first resistor
[tex]0.794=\dfrac{e^2}{100+r}[/tex]....(I)
For second resistor
[tex]0.401=\dfrac{e^2}{200+r}[/tex].....(II)
From equation (I) and (II)
[tex]\dfrac{795}{401}=\dfrac{200+r}{100+r}[/tex]
Using component of dividend rule
[tex]\dfrac{393}{401}=\dfrac{100}{100+r}[/tex]
[tex]r =2.04\ \Omega[/tex]
Now, Put the value of internal resistance in equation (I)
[tex]0.794=\dfrac{e^2}{100+2.04}[/tex]
[tex]e^2=0.794(100+2.04)[/tex]
[tex]e=\sqrt{0.794(100+2.04)}[/tex]
[tex]e=9\ volt[/tex]
Hence, The emf and internal resistance of the battery are 9 volt and 2.04 Ω
