Find the dimensis of
a. the specific heat capacity c,
b. the coeficient of linear expansion `alpha` and
c. the gas constant R
Some of te equations involving these quantities are
` Q=mt(T_2-T_1), l_t=l_0[1+alpha(T_2-T_1) and PV=nRT.`

Find the dimensions of a. the specific heat capacity c, b. the coeficient of linear expansion alpha and c. the gas constant R Some of the equations involving these quantities are Q=mc(T_2-T_1), l_t=l_0[1+alpha(T_2-T_1)] and PV=nRT.

Find the dimensions of a. the specific heat capacity c, b. the coeficient of linear expansion alpha and c. the gas constant R Some of the equations involving these quantities are Q=mc(T_2-T_1), l_t=l_0[1+alpha(T_2-T_1)] and PV=nRT.

Find the dimensions of (a) the specific heat capacity c, (b) the coefficient of linear expansion alpha and (c) the gas constant R. Some of the equations these quantities are Q=mc(T_(2)-T_(1)) l_(t)=l_(0)[1+alpha (T_(2)-T_(1))] and PV=nRT. (Where Q=heat enegry , m=mass, T_(1)&T_(2) = temperatures, l_(1) =length at temperature t^(@)C , l_(0)= length at temperature 0^(@) C , P=Pressure, v = volume, n = mole)

Find the dimensions of a. angular speed omega angular acceleration alpha torque tau and d. moment of interia I . . Some of the equations involving these quantities are omega=(theta_2-theta_1)/(t_2-t_1), alpha = (omega_2-omega_1)/(t_2-t_1), tau= F.r and I=mr^2 The symbols have standard meanings.

Find the dimensions of a. angular speed omega angular acceleration alpha torque tau and d. moment of interia I. . Some of the equations involving these quantities are omega=(theta_2-theta_1)/(t_2-t_1), alpha = (omega_2-omega_1)/(t_2-t_1), tau= F.r and I=mr^2 The symbols have standard meanings.

Find the dimensions of a. angular speed omega angular acceleration alpha torque tau and d. moment of interia I . . Some of the equations involving these quantities are omega=(theta_2-theta_1)/(t_2-t_1), alpha = (omega_2-omega_1)/(t_2-t_1), tau= F.r and I=mr^2 The symbols have standard meanings.

A rod of length l and coefficient of linear expansion alpha . Find increase in length when temperature changes from T to T+ DeltaT

A rod of length l and coefficient of linear expansion alpha . Find increase in length when temperature changes from T to T+ DeltaT

For an ideal gas the equation of a process for which the heat capacity of the gas varies with temperatue as C=(alpha//T(alpha) is a constant) is given by

For an ideal gas the equation of a process for which the heat capacity of the gas varies with temperatue as C=(alpha//T(alpha) is a constant) is given by