For `Ag^(+)(aq) + 2NH_(3(aq)) harr Ag(NH_(3))_(2(aq))^(+)` `k = 1.7 xx 10^(7)` at `25^(@)C`, for this equilibrium state, which is correct?

Observe the following equations NH_(3) + Ag^(+) hArr (Ag (NH_(3)) ]^(+) , " " K_(1) = 1.6 xx 10^(3) [ Ag(NH_(3) ]^(+) + NH_(3) hArr [ Ag (NH_(3))_(2) ]^(+), K_(2) = 6.8 xx 10^(3) the equilibrium constant for the following reaction, Ag^(+) + 2NH_(3) hArr [ Ag (NH_(3))_(2) ]^(+) is

The equilibrium constant for the ionisation of RNH_(2(g)) in water as RNH_(2(g)) + H_(2)O_((l)) hArr "RNH"_(3(aq))^(+) + OH_((aq))^(-) is 8 xx 10^(-6) at 25^(@) C . Find the pH of a solution at equilibrium when pressure of RNH_(2(g)) is 0.5 bar.

At 298 K, the molar equilibrium concentrations of Ag^(+) , NH_(3) and [Ag (NH_(3))_(2)]^(+) for the equilibrium Ag_((aq))^(+) + 2 NH_(3 (aq)) hArr [Ag (NH_(3))_(3)]_(aq)^(+) were found to be 10^(-1) , 10^(-3) , and 10^(-1) respectively . The value of K_(C) is

Calculate the concentration of free silver ion [Ag^(+) ] in an aqueous solution that is prepared as 0.1 M AgNO_3 and 3.0 M NH_3 ,Ag^(+) (aq) +2 NH_3 (aq) hArr [Ag(NH_3) _2]^(+) (aq) K_(f) = 1.6 xx 10^(7) . If answer is x xx 10^(-10) M then x= ______?

Fe_((aq))^(+3)+SCN_((aq))^(-) harr [Fe(SCN)]_(aq)^(+2) is an example of

Ag^(+) + NH_3 hArr [Ag(NH_3)]^(+) , K_1=3.5xx10^(-3) , [Ag(NH_3)]^(+) + NH_3 hArr [Ag(NH_3)_2]^(+) , K_2=1.7xx10^(-3) . Calculate the formation constant of [Ag(NH_3)_2]^+ . What is the instability constant ?

i) H_3PO_(4(aq)) iff H^ _(aq)+ H_2PO_(4(aq))^- ii) H_2PO_(4(aq))^- iff H^ +(aq)+ H_2PO_(4(aq))^(2-) . iii) H_2PO_(4(aq))^(2-) iff H^ +(aq)+ PO_(4(aq))^(3-) . The equilibrium constantsfor the above reactions at a certain temperature are K_1, K_2 and K_3 respectively. The equilibrium constant for the reaction. H_3PO_4(aq) iff 3H^ +(aq)+ PO_(4(aq))^(3-) in terms K_1, K_2 and K_3 is

Calculate the standard cell potentials of galvanic cell in which the following reactions take place. (i) 2Cr(s) + 3Cd^(2+)(aq) to 2Cr^(3+) (aq) + 3Cd (ii) Fe^(2+)(aq) + Ag^(+)(aq) to Fe^(3+)(aq) + Ag(s) Calculate the ΔrG and equilibrium constant of the reactions.

I_(2(aq)) + I_((aq))^(-) hArr I_(3(aq))^(-). We started with I mole of I_(2) and 0.5 mole of l^(-) in one litre flask. After equilibrium is reached, excess of AgNO_(2) gave 0.25 mole of yellow precipitate. Equilibrium constant is