A point mass m is suspended usin two wires of different material as shown in the figure. If corss-section of wire-1 and sore-2 are `3mm ^(2) and sqrt(3) mm^(2)` respectively, which of the following is correct?

A rod of length 1.05 m having negliaible mass is supported at its ends by two wires of steel (wire A) and aluminium (wire B) of equal lengths as shown in fig. The cross-sectional area of wire A and B are 1 mm^(2) and 2 mm^(2) , respectively . At what point along the rod should a mass m be suspended in order to produce (a) equal stresses and (b) equal strains in both steel and aluminium wires. Given, Y_(steel) = 2 xx 10^(11) Nm^(-2) and Y-(alumi n i um) = 7.0 xx 10^(10)N^(-2)

A rod of length 1.05 m having negliaible mass is supported at its ends by two wires of steel (wire A) and aluminium (wire B) of equal lengths as shown in fig. The cross-sectional area of wire A and B are 1 mm^(2) and 2 mm^(2) , respectively . At what point along the rod should a mass m be suspended in order to produce (a) equal stresses and (b) equal strains in both steel and aluminium wires. Given, Y_(steel) = 2 xx 10^(11) Nm^(-2) and Y-(alumi n i um) = 7.0 xx 10^(10)N^(-2)

An iron rod B of length 1 m and mass 1 kg is suspended with help of two wires as shwon in figure. The area of cross-section of iron wire is 0.3 cm^(2) and of copper wire is 0.6cm^(2) . At what distance from iron wire a weight can be hung to produce equal stress in wires?

In the given circuit, AB is a wire of resistance 6Omega , length 10 cm, number of electrons per unit volume in meterial of wire is 10^(29)m^(-3) . If cross-sectional area of wire is 1mm^(2) , then which of the following options are correct?

The slope of graph as shown in figure at points 1,2 and 3 is m_(1), m_(2) and m_(3) respectively then

An iron rod B of length 1 m and mass 1 kg is suspended with help of two wires as shwon in figure. The area of cross-section of iron wire is 0.3 cm^(2) and of copper wire is 0.6cm^(2) . In the above question, if Y_("iron"):Y_(Cu)=2:1 , then the ratio of elastics energy per unit volume stored in iron wire to copper wire is

A block of weight 100 N is suspended by copper and steel wires of same cross sectional area 0.5 cm^(2) and, length sqrt(3) m and 1m, respectively. Their other ends are fixed on a ceiling as shown in figure. The angles subtended by copper and steel wires with ceiling are 30^(@) and 60^(@) , respectively. If elongation in copper wire is (Delta l_(C)) and elongation in steel wire is (Delta l_(s)) , then the ratio (Delta l_(C))/(Delta l_(s)) is - [Young's modulus for copper and steel are 1 xx 10^(11) N//m^(2) and 2 xx 10^(11) N//m^(2) , respectively]

Two rods A and B , each of equal length for different materials are suspended from a common support as shown in the figure. The rods A and B can support a maximum load of W_(1)=600N and W_(2)=6000N respectively. If their cross sectional area are A_(1)=10mm^(2) and A_(2)=1000mm^(2) , respectively then identify the stronger material.

Two wires of equal length and cross-section area suspended as shown in figure. Their Young's modulus are Y_(1) and Y_(2) respectively. The equavalent Young's modulus will be

When a load of 10 kg is suspended on a metallic wire, its length increase by 2 mm. The force constant of the wire is