`Zn+Cu^(2+)(aq)toCu+Zn^(2+)(aq)`.
Reaction quotient is `Q=([Zn^(2+)])/([Cu^(2+)])*E_(cell)^(@)=1.10V` ltb rgt `E_(cell)` will be 1.1591 V when :

Consider the cell reaction Zn+Cu^(2+)(aq)iff Cu + Zn^(2+) (aq). Reaction quotient is Q = ([Zn^(2+)])/([Cu^(2+)])E^(0) of the cell is 1.10V. Now, E_(cell) will be 1.159V when:

Zn+Cu^(2+)(aq)hArrCu+Zn^(2+)(aq). Reaction quotient is Q=([Zn^(2+)])/([Cu^(2+)]) . Variation of E_(cell) with log Q is of the type with OA=1.10 V.E_(cell) will be 1.1591V when

Zn+Cu^(2+)(aq)hArrCu+Zn^(2+)(aq). Reaction quotient is Q=([Zn^(2+)])/([Cu^(2+)]) . Variation of E_(cell) with log Q is of the type with OA=1.10 V.E_(cell) will be 1.1591V when

Reaction quotient (Q) for Daniell cell is frac{[Zn^(+2)]}{[Cu^(+2)]} . Calculate its value if E_(cell) is 1.1591 and E_(cell)^o is 1.10 volts.

Consider the following reaction, Zn(s)+Cu^(2+) (0.1 M) rarr Zn^(2+) (1 M)+Cu(s) above reaction, taking place in a cell, E_("cell")^(@) is 1.10 V. E_("cell") for the cell will be (2.303 (RT)/(F)=0.0591)

For the redox reaction Zn(s) + Cu^(2+) (0.1M) rarr Zn^(2+) (1M) + Cu(s) that takes place in a cell, E^(o)""_(cell) is 1.10 volt. E_(cell) for the cell will be:

Mg(s)|Mg^(2+)(aq)||Zn^(2+)(aq)|Zn(s),E^(@)=+3.13V The correct plot of E_("cell") versus log.([Mg^(2+)])/([Zn^(2+)]) will be represented as

A Daniell cell : Zn|Zn^(2+)||Cu^(2+)|Cu with E_(cell)=1.1V is given. Is this a spontaneous cell?

Find out the E_("cell")^(@) from the given data (a) Zn|Zn^(+2)|| Cu^(+2)| Cu, E_("cell")^(@) = 1.10V (b) Cu| Cu^(+2)|| Ag^(+)|Ag, E_("cell")^(@) = 0.46V ( c) Zn|Zn^(+2)||Ag^(+) | Ag, E_("cell")^(@) = ? (Given E_(Cu^(+2)//Cu)^(@) = 0.34V )

Given that (at T = 298 K) Cu(s) | Cu^(2+)(1.0M) || Ag^(+)(1.0M)| Ag(s) underset(E_(cell)^(@) = 0.46V Zn(s) | Zn^(2+) (1.0M) || Cu^(2+) (1.0M) | Cu(s) underset(E_(cell)^(@) = 1.10V Then E_(cell) for, Zn | Zn^(2+)(0.1M) || Ag^(+)(0.1M) | Ag at 298 K will be: