At `1400 K, K_( c) = 2.5 xx 10^(-3)` for the reaction
`CH_(4)(g)+2H_(2)S(g)hArrCS_(2)(g)+4H_(2)(g)`
A ` 10 L` reaction vessel at `1400 K` contains `2.0 mol` of `CH_(4)`, `4.0 mol` of `H_(2)S` ,`3.0 mol` of `CS_(2)`, `3.0 mol` of `H_(2)`. In which direction does the reaction proceed to reach equilibrium?

At 1400 K, K_c=2.5xx10^(-3) for the reaction CH_4(g)+2H_2S(g)hArrCS_2(g)+4H_2(g) .A 10.0 L reaction vessel at 1400 K contains 2.00 mole of CH_4 .3.0 mole of CS_2 ,3.0 mole of H_2 and 4.0 mole of H_2S .Then

What is the unit of K_(p) for the reaction ? CS_(2)(g)+4H_(2)(g)hArrCH_(4)(g)+2H_(2)S(g)

The reaction, CO(g)+3H_(2)(g) hArr CH_(4)(g)+H_(2)O(g) is at equilibrium at 1300 K in a 1 L flask. It also contains 0.30 mol of CO, 0.10 mol of H_(2) and 0.02 mol of H_(2)O and an unknown amount of CH_(4) in the flask. Determine the concentration of CH_(4) in the mixture. The equilibrium constant K_(c ) for the reaction at the given temperature us 3.90 .

An equilibrium mixture CO(g)+H_(2)O(g) hArr CO_(2)(g)+H_(2)(g) present in a vessel of one litre capacity at 815^(@)C was found by analysis to contain 0.4 mol of CO, 0.3 mol of H_(2)O, 0.2 mol of CO_(2) and 0.6 mol of H_(2) . a. Calculate K_(c) b. If it is derived to increase the concentration of CO to 0.6 mol by adding CO_(2) to the vessel, how many moles must be addes into equilibrium mixture at constant temperature in order to get this change?

The equilibrium constant for the reaction : N_(2)(g)+3H_(2)(g)hArr2NH_(3)(g)" at 715 K is "6.0xx10^(-2) . If, in a particular reaction, there are 0.25" mol L"^(-1) of H_(2) and 0.06" mol L"^(-1) of NH_(3) present, calculate the concentration of N_(2) at equilibrium.

K_(C) " for " H_(2) (g)+ 1//2 O_(2)(g) rArr H_(2) O (l)at 500 K is 2.4 xx 10^(47), K_(p) of the reaction is .

What is DeltaG^(ɵ) for the following reaction? 1/2 N_(2)(g)+3/2 H_(2)(g) hArr NH_(3)(g), K_(p)=4.42xx10^(4) at 25^(@)C

What is DeltaG^(ɵ) for the following reaction? 1/2 N_(2)(g)+3/2 H_(2)(g) hArr NH_(3)(g), K_(p)=4.42xx10^(4) at 25^(@)C

Equilibrium constant, K_(c) for the reaction, N_(2(g))+3H_(2(g))hArr2NH_(3(g)) , at 500 K is 0.061 litre^(2) "mole"^(-2) . At a particular time, the analysis shows that composition of the reaction mixture is 3.00 mol litre^(-1)N_(2) , 2.00 mol litre^(-1)H_(2) , and 0.500 mol litre^(-1)NH_(3) . Is the reaction at equilibrium? If not, in which direction does the reaction tend to proceed to reach equilibrium?

Calculate K_(c) for the reaction: 2H_(2)(g)+S_(2)(g) hArr 2H_(2)S(g) if 1.58 mol H_(2)S, 1.27 mol H_(2) and 2.78xx10^(-6) mol of S_(2) are in equilibrium in a flask of capacity 180 L at 750^(@)C .