[" If the radius and surface tension of a spherical soap bubble are "'R" ' and ' "T" respectively,then "],[" show that the charge required to double its radius would be,"8 pi R[varepsilon_(0)R[7p_(0)R+12T]]^(1/2)" ,where "],[p_(0)" is the atmospheric pressure."]

If the radius and surface tension of a spherical soap bubble are 'R' and 'T' respectively, Then show that the charge required to double its radius would be 8piR ,[epsilon_(0)R[7p_(0)R+12T]]^(1/2) . Where p_(0) is the atmospheric pressure.

If the radius and surface tension of a spherical soap bubble are 'R' and 'T' respectively, Then show that the charge required to double its radius would be 8piR ,[epsilon_(0)R[7p_(0)R+12T]]^(1/2) . Where p_(0) is the atmospheric pressure.

If r and T are radius and surface tension of a spherical soap bubble respectively then find the charge needed to double the radius of bubble.

If r and T are radius and surface tension of a spherical soap bubble respectively then find the charge needed to double the radius of bubble.

If the radius and surface tension of a spherical soap bubble be r and T respectively. Find the charge uniformly distributed over the outer surface of the bubble, is required to double its radius. (Given that atmospheric pressure is P_(0) and inside temperature of the bubble during expansion remains constant.)

If the radius and surface tension of a spherical soap bubble be r and T respectively. Find the charge uniformly distributed over the outer surface of the bubble, is required to double its radius. (Given that atmospheric pressure is P_(0) and inside temperature of the bubble during expansion remains constant.)

A soap bubble of radius r and surface tension T is given a potential V. Show that the new radius R of the bubble is related with the initial radius by the equation P(R^(3) -r^(3)) +4T (R^(2)-r^(2)) = (in_(0)V^(2)R)/(2) where P is the atmospheric pressure.