A vessel containing one gram -mole of oxygen is enclosed in a thermally insulated vessel. The vessel is next moved with a constant speed `v_(0)` and then suddenly stopped. The process results in a rise in the temperature of the gas by `1^(@)c`. Calculate the speed `v_(0)`.

A vessel containing one gram-mole of oxygen is enclosed in a thermally insulated vessel. The vessel is than moved with a constant speed v_0 and then suddenly stopped. The process results in a rise in the temperature of the gas by 1^@C . Calculate the speed v_0 .

One gram mole of oxygen at 27^@ and one atmospheric pressure is enclosed in vessel. (i) Assuming the molecules to be moving the V_(rms) , Find the number of collisions per second which the molecules make with one square metre area of the vessel wall. (ii) The vessel is next thermally insulated and moved with a constant speed V_0 . It is then suddenly stopped. The process results in a rise of the temperature of the gas by 1^@C . Calculate the speed V_0 .

1 g mole of oxygen at 27^@ C and (1) atmosphere pressure is enclosed in a vessel. (a) Assuming the molecules to be moving with (v_(r m s) , find the number of collisions per second which the molecules make with one square metre area of the vessel wall. (b) The vessel is next thermally insulated and moves with a constant speed (v_(0) . It is then suddenly stoppes. The process results in a rise of temperature of the temperature of the gas by 1^@ C . Calculate the speed v_0.[k = 1.38 xx 10^-23 J//K and N_(A) = 6.02 xx 10^23 //mol] .

1 g mole of oxygen at 27^@ C and (1) atmosphere pressure is enclosed in a vessel. (a) Assuming the molecules to be moving with (v_(r m s) , find the number of collisions per second which the molecules make with one square metre area of the vessel wall. (b) The vessel is next thermally insulated and moves with a constant speed (v_(0) . It is then suddenly stoppes. The process results in a rise of temperature of the temperature of the gas by 1^@ C . Calculate the speed v_0.[k = 1.38 xx 10^-23 J//K and N_(A) = 6.02 xx 10^23 //mol] .

Certain amount of an ideal gas is contained in a closed vessel. The vessel is moving with a constant velcity v . The molecular mass of gas is M . The rise in temperature of the gas when the vessel is suddenly stopped is (gamma C_(P) // C_(V))

Certain amount of an ideal gas is contained in a closed vessel. The vessel is moving with a constant velcity v . The molecular mass of gas is M . The rise in temperature of the gas when the vessel is suddenly stopped is (gamma C_(P) // C_(V))

Certain amount of an ideal gas is contained in a closed vessel. The vessel is moving with a constant velcity v . The molecular mass of gas is M . The rise in temperature of the gas when the vessel is suddenly stopped is (gamma C_(P) // C_(V))