Two identical conducting rods are first connected independently to two vessels, one containing water at `100^(@)C` and the other containing ice at `0^(@)C`. In the second case, the rods are joined end to end connected to the same vessels. Let `m_(1) and m_(2)` g/s be the rate of melting of ice in the two cases respectively, the ratio `(m_(1))/(m_(2))` is

Two identical conducting rods are first connected independently to two vessels, one containing water at 100^@C and the other containing ice at 0^@C . In the second case, the rods are joined end to end and connected to the same vessels. Let q_1 and q_2 gram per second be the rate of melting of ice in the two cases respectively. The ratio q_1/q_2 is (a) 1/2 (b) 2/1 (c) 4/1 (d) 1/4

Two identical rods are connected between two containers on of tehm is at 100^@C and another is at 0^@C. If rods are connected in parralel them the rate of melting of ice is q_1 gm//sec. If they are connected in series then the rate is q_2. The ratio q_2//q_1 is

Two identical rods are connected between two containers. One of them is at 100^(@)C containing water and another is at 0^(@)C containing ice. If rods are connected in parallel then the rate of melting of ice is q_(1)g//s . If they are connected in series then teh rate is q_(2)g//s . The ratio q_(2)//q_(1) is

One end of conducting rod is maintained at temperature 50^(@)C and at the other end ice is melting at 0^(@)C . The rate of melting of ice is doubled if:

Two identical rods are connected in parallel. One end of the rods is maintained at 100^(@)C and other end is kept in 0^(@)C ice . The rate at which the ice melts is Q_(1) gm/sec . Now the rods are connected in series . The ends are again maintained at 100^(@) C and kept in 0^(@)C ice . Now the rate at which ice melts is Q_(2) gm/sec . Then Q_(2) //Q_(1) is

One end of a cylindrical rod is kept in steam chamber and the other end in melting Ice. Now 0.5gm of ice melts in 1sec if the rod is replaced by another rod of same length half the diameter then rate of melting of ice will be (in gm/sec) .

One end of 0.5 m long metal rod is in steam at 100^@C and the other end is put in ice at 0^@C . If ice melts at the rate of 10 g/min, calculate the thermal conductivity of the metal. Take, cross sectional area of rod = 2pi cm^2 . Latent ice of heat = 80 cal/g

Two identical rods each of mass m and length are connected as shown. Locate c.m.

A vessel contains 10^(–1) kg of ice at 0^(@)C . Now steam is passed into the vessel to melt ice. Neglecting the thermal capacity of the vessel, find the mass of water in the vessel when all ice melts into water.

A mass m of steam at 100^(@)C is to passed into a vessel containing 10g of ice and 100g of water at 0^(@)C so that all the ice is melted and the temperature is raised to 5^(@)C neglecting heat absorbed by the vessel, we get