314155
A rubber balloon permeable to all isotopic forms of hydrogen is filled with heavy hydrogen and placed in tank of pure hydrogen. After some time, the balloon will
1 Shrink in size
2 Expand
3 Remain as such
4 Shrink to half of the size
Explanation:
Due to more diffusion of pure hydrogen than heavy hydrogen. According to Graham's law, higher is the molar mass lower is the diffusion. Pure hydrogen has lower molecular mass than heavy hydrogen.
CHXI06:STATES OF MATTER
314156
The densities of \(\mathrm{\mathrm{CH}_{4}}\) and \(\mathrm{\mathrm{O}_{2}}\) are in the ratio \(\mathrm{1: 2}\). The ratio of rates of diffusion of oxygen and methane is
314157
According to Graham's law at a given temperature the ratio of diffusion \(\mathrm{r_{A} / r_{B}}\) of gases \(\mathrm{\mathrm{A}}\) and \(\mathrm{\mathrm{B}}\) is given by
According to Graham's law of diffusion, \(\mathrm{r \propto \dfrac{P}{\sqrt{M}}}\) \(\frac{{{{\rm{r}}_{\rm{A}}}}}{{{{\rm{r}}_{\rm{B}}}}}{\rm{ = }}\frac{{{{\rm{P}}_{\rm{A}}}}}{{{{\rm{P}}_{\rm{B}}}}} \cdot \sqrt {\frac{{{{\rm{M}}_{\rm{B}}}}}{{{{\rm{M}}_{\rm{A}}}}}} \,\,{\rm{or}}\,\,\frac{{{{\rm{r}}_{\rm{A}}}}}{{{{\rm{r}}_{\rm{B}}}}}{\rm{ = }}\frac{{{{\rm{P}}_{\rm{A}}}}}{{{{\rm{P}}_{\rm{B}}}}}{\left[ {\frac{{{{\rm{M}}_{\rm{B}}}}}{{{{\rm{M}}_{\rm{A}}}}}} \right]^{{\rm{1/2}}}}\)
CHXI06:STATES OF MATTER
314158
Assuming that at S.T.P. gas A has a density of 0.09 gram per litre and gas B has a density of 1.43 gram per litre, the ratio between the rates of diffusion of \(\mathrm{\mathrm{A}}\) and \(\mathrm{\mathrm{B}}\) is
314155
A rubber balloon permeable to all isotopic forms of hydrogen is filled with heavy hydrogen and placed in tank of pure hydrogen. After some time, the balloon will
1 Shrink in size
2 Expand
3 Remain as such
4 Shrink to half of the size
Explanation:
Due to more diffusion of pure hydrogen than heavy hydrogen. According to Graham's law, higher is the molar mass lower is the diffusion. Pure hydrogen has lower molecular mass than heavy hydrogen.
CHXI06:STATES OF MATTER
314156
The densities of \(\mathrm{\mathrm{CH}_{4}}\) and \(\mathrm{\mathrm{O}_{2}}\) are in the ratio \(\mathrm{1: 2}\). The ratio of rates of diffusion of oxygen and methane is
314157
According to Graham's law at a given temperature the ratio of diffusion \(\mathrm{r_{A} / r_{B}}\) of gases \(\mathrm{\mathrm{A}}\) and \(\mathrm{\mathrm{B}}\) is given by
According to Graham's law of diffusion, \(\mathrm{r \propto \dfrac{P}{\sqrt{M}}}\) \(\frac{{{{\rm{r}}_{\rm{A}}}}}{{{{\rm{r}}_{\rm{B}}}}}{\rm{ = }}\frac{{{{\rm{P}}_{\rm{A}}}}}{{{{\rm{P}}_{\rm{B}}}}} \cdot \sqrt {\frac{{{{\rm{M}}_{\rm{B}}}}}{{{{\rm{M}}_{\rm{A}}}}}} \,\,{\rm{or}}\,\,\frac{{{{\rm{r}}_{\rm{A}}}}}{{{{\rm{r}}_{\rm{B}}}}}{\rm{ = }}\frac{{{{\rm{P}}_{\rm{A}}}}}{{{{\rm{P}}_{\rm{B}}}}}{\left[ {\frac{{{{\rm{M}}_{\rm{B}}}}}{{{{\rm{M}}_{\rm{A}}}}}} \right]^{{\rm{1/2}}}}\)
CHXI06:STATES OF MATTER
314158
Assuming that at S.T.P. gas A has a density of 0.09 gram per litre and gas B has a density of 1.43 gram per litre, the ratio between the rates of diffusion of \(\mathrm{\mathrm{A}}\) and \(\mathrm{\mathrm{B}}\) is
314155
A rubber balloon permeable to all isotopic forms of hydrogen is filled with heavy hydrogen and placed in tank of pure hydrogen. After some time, the balloon will
1 Shrink in size
2 Expand
3 Remain as such
4 Shrink to half of the size
Explanation:
Due to more diffusion of pure hydrogen than heavy hydrogen. According to Graham's law, higher is the molar mass lower is the diffusion. Pure hydrogen has lower molecular mass than heavy hydrogen.
CHXI06:STATES OF MATTER
314156
The densities of \(\mathrm{\mathrm{CH}_{4}}\) and \(\mathrm{\mathrm{O}_{2}}\) are in the ratio \(\mathrm{1: 2}\). The ratio of rates of diffusion of oxygen and methane is
314157
According to Graham's law at a given temperature the ratio of diffusion \(\mathrm{r_{A} / r_{B}}\) of gases \(\mathrm{\mathrm{A}}\) and \(\mathrm{\mathrm{B}}\) is given by
According to Graham's law of diffusion, \(\mathrm{r \propto \dfrac{P}{\sqrt{M}}}\) \(\frac{{{{\rm{r}}_{\rm{A}}}}}{{{{\rm{r}}_{\rm{B}}}}}{\rm{ = }}\frac{{{{\rm{P}}_{\rm{A}}}}}{{{{\rm{P}}_{\rm{B}}}}} \cdot \sqrt {\frac{{{{\rm{M}}_{\rm{B}}}}}{{{{\rm{M}}_{\rm{A}}}}}} \,\,{\rm{or}}\,\,\frac{{{{\rm{r}}_{\rm{A}}}}}{{{{\rm{r}}_{\rm{B}}}}}{\rm{ = }}\frac{{{{\rm{P}}_{\rm{A}}}}}{{{{\rm{P}}_{\rm{B}}}}}{\left[ {\frac{{{{\rm{M}}_{\rm{B}}}}}{{{{\rm{M}}_{\rm{A}}}}}} \right]^{{\rm{1/2}}}}\)
CHXI06:STATES OF MATTER
314158
Assuming that at S.T.P. gas A has a density of 0.09 gram per litre and gas B has a density of 1.43 gram per litre, the ratio between the rates of diffusion of \(\mathrm{\mathrm{A}}\) and \(\mathrm{\mathrm{B}}\) is
314155
A rubber balloon permeable to all isotopic forms of hydrogen is filled with heavy hydrogen and placed in tank of pure hydrogen. After some time, the balloon will
1 Shrink in size
2 Expand
3 Remain as such
4 Shrink to half of the size
Explanation:
Due to more diffusion of pure hydrogen than heavy hydrogen. According to Graham's law, higher is the molar mass lower is the diffusion. Pure hydrogen has lower molecular mass than heavy hydrogen.
CHXI06:STATES OF MATTER
314156
The densities of \(\mathrm{\mathrm{CH}_{4}}\) and \(\mathrm{\mathrm{O}_{2}}\) are in the ratio \(\mathrm{1: 2}\). The ratio of rates of diffusion of oxygen and methane is
314157
According to Graham's law at a given temperature the ratio of diffusion \(\mathrm{r_{A} / r_{B}}\) of gases \(\mathrm{\mathrm{A}}\) and \(\mathrm{\mathrm{B}}\) is given by
According to Graham's law of diffusion, \(\mathrm{r \propto \dfrac{P}{\sqrt{M}}}\) \(\frac{{{{\rm{r}}_{\rm{A}}}}}{{{{\rm{r}}_{\rm{B}}}}}{\rm{ = }}\frac{{{{\rm{P}}_{\rm{A}}}}}{{{{\rm{P}}_{\rm{B}}}}} \cdot \sqrt {\frac{{{{\rm{M}}_{\rm{B}}}}}{{{{\rm{M}}_{\rm{A}}}}}} \,\,{\rm{or}}\,\,\frac{{{{\rm{r}}_{\rm{A}}}}}{{{{\rm{r}}_{\rm{B}}}}}{\rm{ = }}\frac{{{{\rm{P}}_{\rm{A}}}}}{{{{\rm{P}}_{\rm{B}}}}}{\left[ {\frac{{{{\rm{M}}_{\rm{B}}}}}{{{{\rm{M}}_{\rm{A}}}}}} \right]^{{\rm{1/2}}}}\)
CHXI06:STATES OF MATTER
314158
Assuming that at S.T.P. gas A has a density of 0.09 gram per litre and gas B has a density of 1.43 gram per litre, the ratio between the rates of diffusion of \(\mathrm{\mathrm{A}}\) and \(\mathrm{\mathrm{B}}\) is
