361233 Assertion :
Shape of a liquid drop is governed by force of gravity and surface tension.
Reason :
Excess pressure inside a drop is directly proportional to surface tension.

361234 Two soap bubbles of radii \(r_{1}\) and \(r_{2}\) equals to \(6\;cm\) and \(8\;cm\) are touching each other over a common surface \(S_{1} S_{2}\) whose radius will be

361235 A bubble of \(8\,mm\) diameter is formed in the air. The surface tension of soap solution is \(30\,{\mkern 1mu} dyne/cm.\) The excess pressure inside the bubble is

361236 A soap bubble, having radius of \(1\;mm\), is blown from a detergent solution having a surface tension of \(2.5 \times {10^{ - 2}}\;N/m\). The pressure inside the bubble equals at a point \(Z_{0}\) below the free surface of water in a container. Taking \(g = 10\,m/{s^2}\), density of water \( = {10^3}\;kg/{m^3}\), the value of \({Z_0}\) is :

361233 Assertion :
Shape of a liquid drop is governed by force of gravity and surface tension.
Reason :
Excess pressure inside a drop is directly proportional to surface tension.

361234 Two soap bubbles of radii \(r_{1}\) and \(r_{2}\) equals to \(6\;cm\) and \(8\;cm\) are touching each other over a common surface \(S_{1} S_{2}\) whose radius will be

361235 A bubble of \(8\,mm\) diameter is formed in the air. The surface tension of soap solution is \(30\,{\mkern 1mu} dyne/cm.\) The excess pressure inside the bubble is

361236 A soap bubble, having radius of \(1\;mm\), is blown from a detergent solution having a surface tension of \(2.5 \times {10^{ - 2}}\;N/m\). The pressure inside the bubble equals at a point \(Z_{0}\) below the free surface of water in a container. Taking \(g = 10\,m/{s^2}\), density of water \( = {10^3}\;kg/{m^3}\), the value of \({Z_0}\) is :

361233 Assertion :
Shape of a liquid drop is governed by force of gravity and surface tension.
Reason :
Excess pressure inside a drop is directly proportional to surface tension.

361234 Two soap bubbles of radii \(r_{1}\) and \(r_{2}\) equals to \(6\;cm\) and \(8\;cm\) are touching each other over a common surface \(S_{1} S_{2}\) whose radius will be

361235 A bubble of \(8\,mm\) diameter is formed in the air. The surface tension of soap solution is \(30\,{\mkern 1mu} dyne/cm.\) The excess pressure inside the bubble is

361236 A soap bubble, having radius of \(1\;mm\), is blown from a detergent solution having a surface tension of \(2.5 \times {10^{ - 2}}\;N/m\). The pressure inside the bubble equals at a point \(Z_{0}\) below the free surface of water in a container. Taking \(g = 10\,m/{s^2}\), density of water \( = {10^3}\;kg/{m^3}\), the value of \({Z_0}\) is :

361233 Assertion :
Shape of a liquid drop is governed by force of gravity and surface tension.
Reason :
Excess pressure inside a drop is directly proportional to surface tension.

361234 Two soap bubbles of radii \(r_{1}\) and \(r_{2}\) equals to \(6\;cm\) and \(8\;cm\) are touching each other over a common surface \(S_{1} S_{2}\) whose radius will be

361235 A bubble of \(8\,mm\) diameter is formed in the air. The surface tension of soap solution is \(30\,{\mkern 1mu} dyne/cm.\) The excess pressure inside the bubble is

361236 A soap bubble, having radius of \(1\;mm\), is blown from a detergent solution having a surface tension of \(2.5 \times {10^{ - 2}}\;N/m\). The pressure inside the bubble equals at a point \(Z_{0}\) below the free surface of water in a container. Taking \(g = 10\,m/{s^2}\), density of water \( = {10^3}\;kg/{m^3}\), the value of \({Z_0}\) is :