When a current flows in a wire of resistance R at a constan t potential difference, then the value of heat produced by a current is inversely proportional to:

A current 0.2 A flows in a wire of resistance 15 Omega . Find the potential difference across the ends of the wire.

The current flowing in 3Omega Resistance will be

When a current I flows through a resistance R for time t, the electrical energy spent is :

Statement I: A wire of uniform cross-section and uniform resistivity is connected across an ideal cell. Now the length of the wire is doubled keeping volume of the wire constant. The drift velocity of electrons after stretching the wire becomes one-fouth of what it was before stretching the wire. Statement II: If a wire (of uniform resistivity and uniform cross section) of length l_0 is stretched to length nl_0 , then its resistance becomes n^2 times of what it was before stretching the wire (the volume of wire is kept constant in stretching process). Further at constant potential difference, current is inversely proportional to resistance. Finally, drift velocity of free electron is directly proportional to current and inversely proportional to cross-sectional area of current carrying wire.

Calculate the current flowing through a wire of resistance 5 Omega connected to a battery of potential difference 3 V.

A current of 0.2 A flows through a wire whose ends are at a potential difference of 15 V. Calculate : the heat energy produced in 1 minute.

Calculate the current flowing through a wire of resistance 7.5 Omega connected to a battery of potential difference 1.5. V.

The displacement current flows in the dielectric of a capacitor when the potential difference across its plates-

The displacement current flows in the dielectric of a capacitor when the potential difference across its plates-