If a wire of resistance `20 Omega` is covered with ice and a voltage of `210 V` is applied across the wire , then the rate of melting of ice is

A coil of wire of resistance 50 Omega is embedded in a block of ice. If a potential difference of 210 V is applied across the coil, the amount of ice melted per second will be

A coil of water of resistance 50 Omega is embedded in a block of ice and a potential difference of 210 V is applied across it. The amount of ice which melts in 1 second is [ latent heat of fusion of ice = 80 cal g^(-1) ]

A coil of enamelled copper wire of resistance 50Omega is embedded in a block of ice and a potential difference of 210V applied across it. Calculate the rate of which ice melts. Latent heat of ice is 80 cal per gram.

A coil of enamelled copper wire of resistance 50Omega is embedded in a block of ice and a potential difference of 210V applied across it. Calculate the rate of which ice melts. Latent heat of ice is 80 cal per gram.

A coil of enamelled copper wire of resistance 50 Omega is embedded in a block of ice and a potential difference of 210 V applied across it. Calculate, how much ice will melt in half minute. Latent heat of ice is 180 cal per gram.

ABCD is a square where each side is a uniform wire of resistance 1 Omega . Find a point E on CD such that if a uniform wire of resistance 1 Omega is connected across AE and a constant potential is applied across A and C, the points B and E will be equipotential.

A wire of resistance 5 Omega is bent in the form of a closed circle. Find the resistance across the diameter of the circle.