Assuming that the largest mass that can be moved by a flowing river depends on the velocity of flow, density of river water and acceleration due to gravity , show that the mass varies as the sixth power of velocity of flow.

Assume that the largest stone of mass 'm' that can be moved by a flowing river depends upon the velocity of flow v, the density d & the acceleration due to gravity g. I 'm' varies as the K^(th) power of the velocity of flow, then find the value of K.

The largest mass (m) that can be moved by a flowing river depends on velocity (v), density (rho) of river water and acceleration due to gravity (g). The correct relation is

Assuming that the mass m of the largest stone that can be moved by a flowing river depends upon the velocity upsilon, of water, its density rho and acceleration due to gravity g, then m is directly proportional to

Assuming that the mass m of the largest stone that can be moved by a flowing river depends upon the velocity v of the water , its density rho , and the acceleration due to gravity g . Then m is directly proportinal to

The mass m of the heaviest stone that can be moved by the water flowing in a river depends on speed (v) of water, density (d) of water and the acceleration due to gravity (g). Find the dimension of velocity on which mass of stone depends.

As the depth of the river increases, the velocity of flow

Assume that maximum mass m_(1) of a boulder swept along by a river, depends on the speed V of the river, the acceleration due to gravity g, and the density d of the boulder. Calculate the percentage change in maximum mass of the boulder that can be swept by the river, when speed of the river increases by 1%.

The resistance force arising due to pressure difference at the front and rear sides of a body in a fluid stream depends upon the density of the fluid, the velocity of flow and the maximum area of cross-section perpendicular to the flow. Show that the force varies as the square of the velocity.