A film of soap solution is trapped between a vertical frame and a light wire ab of length 0.1 m. If ` g = 10 m//s^2 ` , then the load mass that should be suspended from the wire to keep it in equilibrium is : ` (sigma = 25 xx 10 ^ (-3) N//m)`

A light wire AB of length 10 cm can slide on a vertical frame as shown in figure. There is a film of soap solution trapped between the frame and the wire. Find the load W that should be suspended from the wire to keep it in equilibrium. Neglect friction. Surface tension of soat solution =25 dyne cm^-1 . Take g=10 ms^-2

A soap film of surface tension 3 xx 10^(-2)N//m formed in a rectangular frame can support a straw as shown in Fig. If g = 10 ms^(-2) , the mass of the straw is

A uniform wire of length 20 m and weighing 5 kg hangs vertically. If g=10 m s^(-2) , then the speed of transverse waves in the middle of the wire is

A load of 4 kg is suspended from a ceiling through a steel wire of length 20 m and radius 2 mm . It is found that the length of the wire increases by 0.031 mm , as equilibrium is achieved. If g = 3.1xxpi ms(-2) , the value of young's modulus of the material of the wire (in Nm^(-2)) is

A wire of mass 5 gm is kept horizontally on the surface of water. What ist he minimum length of the wire so that it does not break the surface film.Surface tension = 72 xx 10^(-3)N//m

A metal wire of length L is suspended vertically from a rigid support. When a bob of mass M is attached to the lower end of wire, the elongation of the wire is l:

PQRS is a rectangular frame of copper wire shown in figure the side RS of the frame is movable. If a soap film is formed on it then what is the diameter of the wire to maintain equilibirum (given surface tension of soap solution =0.045N//m and density of copper =8.96xx10^(3)kg//m^(3))

A soap film in formed on a frame of area 4xx10^(-3)m^(2) . If the area of the film in reduced to half, then the change in the potential energy of the film is (surface tension of soap solution =40xx10^(-3)N//m)

A copper wire of negligible mass, 1 m length and cross-sectional area 10^(-6) m^(2) is kept on a smooth horizontal table with one end fixed. A ball of mass 1 kg is attached to the other end. The wire and the ball are rotating with an angular velocity of 20 rad//s . If the elongation in the wire is 10^(-3) m . a. Find the Young's modulus of the wire (in terms of xx 10^(11) N//m^(2) ). b. If for the same wire as stated above, the angular velocity is increased to 100 rad//s and the wire breaks down, find the breaking stress (in terms of xx 10^(10) N//m^(2) ).

A load of 4.0 kg is suspended from a ceiling through a steel wire of length 20 m and radius 2.0 mm. It is found that the length of the wire increases by 0.031 mm as equilibrium is achieved. Find Young modulus of steel. Take g=3.1pims^-2