The nature of curve of `E_(cell)^(@)` vs. log `K_c` is :

The ratio of slopes of K_(max) vs. V and V_(0) vs. v curves in the photoelectric effect gives (v= freqency. K_(max) = maximum kinetic energy, V_(0) =stopping potential) :

The intercepts and slope of graph of log K_(p)^(@) "Vs" (1)/(T) are :

Electrode potential for Mg electrode varies according to the equation E_(Mg^(2+)|Mg)=E_(Mg^(2+)|Mg)^(ϴ) -(0.059)/2 "log" 1/([Mg^(2+)]) The graph of E_(Mg^(2+)|Mg) vs log [Mg^(2+)] is (a) (b) (c) (d)

Why is equilibrium constant K related to only E_("cell")^(Theta) and not E_("cell") ?

A graph is plotted between E_(cell) and log .([Zn^(2+)])/([Cu^(2+)]) . The curve is linear with intercept on E_(cell) axis equals to 1.10V . Calculate E_(cell) for the cell. Zn(s)||Zn^(2+)(0.1M)||Cu^(2+)(0.01M)|Cu

Electrode potential for Mg electrode varies according to the equation E_(Mg^(2+)|Mg)=E_(Mg^(2+)|Mg)^(ϴ) -(0.059)/2 "log" 1/([Mg^(2+)]) The graph of E_(Mg^(2+)|Mg) vs log [Mg^(2+)] is

Electrode potential for Mg electrode varies according to the equation E_(Mg^(2+)|Mg)=E_(Mg^(2+)|Mg)^(ϴ) -(0.059)/2 "log" 1/([Mg^(2+)]) The graph of E_(Mg^(2+)|Mg) vs log [Mg^(2+)] is

The standard potential of Cl^(c-)|AgCl|Ag half cell is related to that of Ag^(o+)|Ag though the expression. E^(c-)._(Ag^(o+)|Ag)=E^(c-)._(Cl^(c-)|AgCl|A)+(RT)/(F)ln K_(sp)(AgCl) True/False

The area bounded by the curves y=log_e x and y=(log_e x)^2 is (A) e-2 sq. units (B) 3-e sq. units (C) e sq. units (D) e-1 sq. units

A graph plotted between log t_((1)/(2)) vs log concentration is a straight line. What is your conclusion? [Given : n = order of reaction]