369907 Wires \(A{\text{ and}}\,B\) are made from the same material. A has twice the diameter and three times the length of \(B\). If the elastic limits are not reached, when each is stretched by the same tension, the ratio of energy stored in the \(A\) to that in \(B\) is

369908 Wires \(A\) and \(B\) are made from the same material. A has twice the diameter and three times the length of \(B\). If the elastic limits are not reached, when each is stretched by the same tension, the ratio of energy stored in the A to that in \(B\) is

369909 A \(1 m\) long steel wire of cross-sectional area \(1\;m{m^2}\) is extended by \(1\;mm.\) If \(Y = 2 \times {10^{11}}N{m^{ - 2}}\) then the work done is

369910 A stretched wire of a material whose Young's modulus \(Y = 2 \times {10^{11}}N{m^{ - 2}}\) has Poisson's ratio 0.25. Its lateral strain \(\varepsilon_{1}=10^{-3}\). The elastic energy density of the wire is

369907 Wires \(A{\text{ and}}\,B\) are made from the same material. A has twice the diameter and three times the length of \(B\). If the elastic limits are not reached, when each is stretched by the same tension, the ratio of energy stored in the \(A\) to that in \(B\) is

369908 Wires \(A\) and \(B\) are made from the same material. A has twice the diameter and three times the length of \(B\). If the elastic limits are not reached, when each is stretched by the same tension, the ratio of energy stored in the A to that in \(B\) is

369909 A \(1 m\) long steel wire of cross-sectional area \(1\;m{m^2}\) is extended by \(1\;mm.\) If \(Y = 2 \times {10^{11}}N{m^{ - 2}}\) then the work done is

369910 A stretched wire of a material whose Young's modulus \(Y = 2 \times {10^{11}}N{m^{ - 2}}\) has Poisson's ratio 0.25. Its lateral strain \(\varepsilon_{1}=10^{-3}\). The elastic energy density of the wire is

369907 Wires \(A{\text{ and}}\,B\) are made from the same material. A has twice the diameter and three times the length of \(B\). If the elastic limits are not reached, when each is stretched by the same tension, the ratio of energy stored in the \(A\) to that in \(B\) is

369908 Wires \(A\) and \(B\) are made from the same material. A has twice the diameter and three times the length of \(B\). If the elastic limits are not reached, when each is stretched by the same tension, the ratio of energy stored in the A to that in \(B\) is

369909 A \(1 m\) long steel wire of cross-sectional area \(1\;m{m^2}\) is extended by \(1\;mm.\) If \(Y = 2 \times {10^{11}}N{m^{ - 2}}\) then the work done is

369910 A stretched wire of a material whose Young's modulus \(Y = 2 \times {10^{11}}N{m^{ - 2}}\) has Poisson's ratio 0.25. Its lateral strain \(\varepsilon_{1}=10^{-3}\). The elastic energy density of the wire is

369907 Wires \(A{\text{ and}}\,B\) are made from the same material. A has twice the diameter and three times the length of \(B\). If the elastic limits are not reached, when each is stretched by the same tension, the ratio of energy stored in the \(A\) to that in \(B\) is

369908 Wires \(A\) and \(B\) are made from the same material. A has twice the diameter and three times the length of \(B\). If the elastic limits are not reached, when each is stretched by the same tension, the ratio of energy stored in the A to that in \(B\) is

369909 A \(1 m\) long steel wire of cross-sectional area \(1\;m{m^2}\) is extended by \(1\;mm.\) If \(Y = 2 \times {10^{11}}N{m^{ - 2}}\) then the work done is

369910 A stretched wire of a material whose Young's modulus \(Y = 2 \times {10^{11}}N{m^{ - 2}}\) has Poisson's ratio 0.25. Its lateral strain \(\varepsilon_{1}=10^{-3}\). The elastic energy density of the wire is