314242 According to kinetic equation, Boyles's law can be expressed as

314243 The root mean square velocity of \(\mathrm{1 \mathrm{~mol}}\) of a monoatomic gas having molar mass \(\mathrm{\mathrm{M}}\) is \(\mathrm{v_{r m s}}\). The relation between the average kinetic energy (E) of the gas and \(\mathrm{v_{r m s}}\) is

314244 When universal gas constant (R) is divided by Avogadro number N, then the value \(\mathrm{\mathrm{R} / \mathrm{N}}\) is equivalent to

314245 As the temperature increases, average kinetic energy of molecules increases. What would be the effect of increase of temperature on pressure provided the volume is constant?

314246 Average \(\mathrm{KE}\) of \(\mathrm{CO}_{2}\) at \(27^{\circ} \mathrm{C}\) is E . The average kinetic energy of \(\mathrm{N}_{2}\) at the same temperature will be

314242 According to kinetic equation, Boyles's law can be expressed as

314243 The root mean square velocity of \(\mathrm{1 \mathrm{~mol}}\) of a monoatomic gas having molar mass \(\mathrm{\mathrm{M}}\) is \(\mathrm{v_{r m s}}\). The relation between the average kinetic energy (E) of the gas and \(\mathrm{v_{r m s}}\) is

314244 When universal gas constant (R) is divided by Avogadro number N, then the value \(\mathrm{\mathrm{R} / \mathrm{N}}\) is equivalent to

314245 As the temperature increases, average kinetic energy of molecules increases. What would be the effect of increase of temperature on pressure provided the volume is constant?

314246 Average \(\mathrm{KE}\) of \(\mathrm{CO}_{2}\) at \(27^{\circ} \mathrm{C}\) is E . The average kinetic energy of \(\mathrm{N}_{2}\) at the same temperature will be

314242 According to kinetic equation, Boyles's law can be expressed as

314243 The root mean square velocity of \(\mathrm{1 \mathrm{~mol}}\) of a monoatomic gas having molar mass \(\mathrm{\mathrm{M}}\) is \(\mathrm{v_{r m s}}\). The relation between the average kinetic energy (E) of the gas and \(\mathrm{v_{r m s}}\) is

314244 When universal gas constant (R) is divided by Avogadro number N, then the value \(\mathrm{\mathrm{R} / \mathrm{N}}\) is equivalent to

314245 As the temperature increases, average kinetic energy of molecules increases. What would be the effect of increase of temperature on pressure provided the volume is constant?

314246 Average \(\mathrm{KE}\) of \(\mathrm{CO}_{2}\) at \(27^{\circ} \mathrm{C}\) is E . The average kinetic energy of \(\mathrm{N}_{2}\) at the same temperature will be

314242 According to kinetic equation, Boyles's law can be expressed as

314243 The root mean square velocity of \(\mathrm{1 \mathrm{~mol}}\) of a monoatomic gas having molar mass \(\mathrm{\mathrm{M}}\) is \(\mathrm{v_{r m s}}\). The relation between the average kinetic energy (E) of the gas and \(\mathrm{v_{r m s}}\) is

314244 When universal gas constant (R) is divided by Avogadro number N, then the value \(\mathrm{\mathrm{R} / \mathrm{N}}\) is equivalent to

314245 As the temperature increases, average kinetic energy of molecules increases. What would be the effect of increase of temperature on pressure provided the volume is constant?

314246 Average \(\mathrm{KE}\) of \(\mathrm{CO}_{2}\) at \(27^{\circ} \mathrm{C}\) is E . The average kinetic energy of \(\mathrm{N}_{2}\) at the same temperature will be

314242 According to kinetic equation, Boyles's law can be expressed as

314243 The root mean square velocity of \(\mathrm{1 \mathrm{~mol}}\) of a monoatomic gas having molar mass \(\mathrm{\mathrm{M}}\) is \(\mathrm{v_{r m s}}\). The relation between the average kinetic energy (E) of the gas and \(\mathrm{v_{r m s}}\) is

314244 When universal gas constant (R) is divided by Avogadro number N, then the value \(\mathrm{\mathrm{R} / \mathrm{N}}\) is equivalent to

314245 As the temperature increases, average kinetic energy of molecules increases. What would be the effect of increase of temperature on pressure provided the volume is constant?

314246 Average \(\mathrm{KE}\) of \(\mathrm{CO}_{2}\) at \(27^{\circ} \mathrm{C}\) is E . The average kinetic energy of \(\mathrm{N}_{2}\) at the same temperature will be