Dissociation constant for `Ag(NH_(3))_(2)^(+)` into `Ag^(+)` and `NH_(3)` is `6 xx 10^(-14)`. Calculate `E^(@)` for the half reaction.
`Ag(NH_(3))_(2)^(+) + e rarr Ag + 2NH_(3)`
Given, `Ag^(+) + e rarr Ag` has `E^(@) = 0.799 V`

K_(d) for dissociation of [Ag(NH_(3))_(2)]^(+) into Ag^(+) and NH_(3) is 6 xx 10^(-8) . Calculae E^(@) for the following half reaction. Ag(NH_(3))_(2)^(+) +e^(-) rarr Ag +2NH_(3) Given Ag^(+) +e^(-) rarr Ag, E^(@) = 0.799V

In the chemical reaction, Ag_(2)O+H_(2)O+2e^(-) to 2Ag+2OH^(-)

Calculate the effective atomic number of silver in [Ag(NH_3)_2]^(+)

The hybridisation of Ag in [Ag(NH_3)]_2^(+) complex is

The dissociation constant for [Ag(NH 3 ​ ) 2 ​ ] + into Ag + is 10 −13 at 298K. If E 0 Ag + /Ag ​ =0.8V then E 0 for the half cell [Ag(NH 3 ​ ) 2 ​ ] + +e − →Ag+2NH 3 ​ will be:

The pK_(sp) of AgI is 16.07 if the E^(@) value for Ag^(+)//Ag is 0.7991V , find the E^(@) for the half cell reaction AgI(s) +e^(-) rarr Ag+I^(-)

Calculate standard free energy change for the reaction 2Ag+2H^(+)rarrH_(2)+2Ag^(+) Given : E_(Ag^(+)//Ag)^(@)=+0.80V

Calculate the reduction potential for the following half cell reaction at 298 K. Ag^(+)(aq)+e^(-)toAg(s) "Given that" [Ag^(+)]=0.1 M and E^(@)=+0.80 V

calculate E^(@) of the following half -cell reaction at 298 K: Ag(NH_(3))_(2)^(+)+e^(-) rarr Ag+2NH_(3) (Ag^(+)+e^(-) rarr Ag , E_(Ag^(+)//Ag)^(@)=0.80 V Ag(NH_(3))_(2)^(+) hArr Ag^(+)+2NH_(3) K=6xx10^(-8

Two electrochemical cells are assembled in which the following reactions occur : V^(2)=VO^(2+)+2H^(o+)rarr 2V^(3+)+H_(2)O V^(3+)+Ag^(o+)+H_(2)O rarr VO^(2+)+2H^(o+)+Ag(s) Calculate E^(c-) for half reaction V^(3+)+e^(-)rarr V^(2+) Given : E^(c-)._((Ag^(o+)|Ag))=0.799 E^(c-)=E^(c-)._(V^(4+)|V^(3+))-E^(c-)._(V^(3+)|V^(2+))=0.616V E^(c-)=E^(c-)._(Ag^(o+)|Ag)-E^(c-)._(V^(4+)|V_(3+))=0.439V