[" 6.For the following equilibrium "N(2)...

[" 6.For the following equilibrium "N_(2)O_(4)rightleftharpoons2NO_(2);K_(c)=0.67." If we start with "3" moles of "NO_(2)],[1" mole of "N_(2)O_(4)" in "1L" flask,then "NO_(2)" present at equilibrium is "],[[" (a) "1.51mol," (b) "2.02mol," (c) "1.17mol," (d) "1.01m]]

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Initially 0.4 mole of N_(2) and 0.9 mole of O_(2) were mixed then moles of N_(2),O_(2) and NO at equilibrium are (approximate):

" Q.2"[" At "30^(@)C" ,the gaseous mixture for the equilibrium,"N_(2)(g)+O_(2)(g)rightleftharpoons2NO(g)" contains "56gm" of "N_(2)" ,"128gm" of "O_(2)" and "],[120gm" of "NO" at equilibrium weights at one atmosphere pressure.The value of "K_(P)" at "30^(@)C" is "]

If alpha is the degree of dissociation of N_(2)O_(4) in the reaction : N_(2)O_(4)hArr 2NO_(2) then at equilibrium, the total number of moles of N_(2)O_(4) and NO_(2) present is :

2SO_(2)+O_(2)hArr 2SO_(3) . Starting with 2 moles SO_(2) and 1 mole O_(2) in 1L flask, mixture required 0.4 mole MnO_(4)^(-) in acidic medium. Hence, K_9c) is

For the following equilibrium in gaseous phase, N_(2)O_(4)hArr 2NO_(2) NO_(2) is 50% of the total volume, when equilibrium is set up. Hence, percent dissociation of N_(2)O_(4) is :

In a 1 lit. Container following equilibrium is estabilished with equal moles of NO_(2)(g) & N_(2)O_(4)(g) . N_(2)O_(4)(g) hArr 2NO_(2)(g) hArr 2NO_(2)(g) at equilibrium M_(avg.)=(184)/(3) , then ratio of K_(c) & total initial mole is .

[" 6.For the following equilibrium "N_(2)O_(4)rightleftharpoons2NO_(2);K_(c)=0.67." If we start with "3" moles of "NO_(2)],[1" mole of "N_(2)O_(4)" in "1L" flask,then "NO_(2)" present at equilibrium is "],[[" (a) "1.51mol," (b) "2.02mol," (c) "1.17mol," (d) "1.01m]]

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