The graph between `log k` versus `1//T` is a straight line.

For a reaction having rate constant k at a temperature T, when a graph between ln k and 1/T is drawn a straight line is obtained. The point at which line cuts y -axis and x -axis respectively correspond to the temperature:

Rate constant k of a reaction varies with temperature according to the equation logk = constant -E_a/(2.303R)(1/T) where E_a is the energy of activation for the reaction . When a graph is plotted for log k versus 1/T , a straight line with a slope - 6670 K is obtained. Calculate the energy of activation for this reaction

Rate constant k of a reaction varies with temperature according to equation: log k= constant - (E_a)/( 2.303 R).(1)/(T ) What is the activation energy for the reaction. When a graph is plotted for log k versus 1/T a straight line with a slope-6670 K is obtained. Calculate energy of activation for this reaction (R=8.314 JK^(-1) mol^(-) 1)

Rate constant k of a reaction varies with temperature according to equation: log k= constant - (E_a)/( 2.303 R).(1)/(T ) What is the activation energy for the reaction. When a graph is plotted for log k versus 1/T a straight line with a slope-6670 K is obtained. Calculate energy of activation for this reaction (R=8.314 JK^(-1) mol^(-) 1)

Rate constant k of a reaction varies with temperature according to equation: log k= constant - (E_a)/( 2.303 R).(1)/(T ) What is the activation energy for the reaction. When a graph is plotted for log k versus 1/T a straight line with a slope-6670 K is obtained. Calculate energy of activation for this reaction (R=8.314 JK^(-1) mol^(-) 1)

Cu^(2+)+2e^(-) rarr Cu . For this, graph between E_(red) versus ln[Cu^(2+)] is a straight line of intercept 0.34V , then the electrode oxidation potential of the half cell Cu|Cu^(2+)(0.1M) will be

Cu^(2+)+2e^(-) rarr Cu . For this, graph between E_(red) versus ln[Cu^(2+)] is a straight line of intercept 0.34V , then the electrode oxidation potential of the half cell Cu|Cu^(2+)(0.1M) will be

A graph plotted between log k versus 1//T for calculating activation energy is shown by

Rate constant 'k' of a reaction varies with temperature 'T' according to the equation: log K = log A -E_a =(E_a)/(2.303 R) ((1)/(T)) where E_a is the activation energy. When a graph is plotted for log ,k vs (1)/(T ) a straight line with a slope of - 4250 K is obtained. Calculate ‘ E_a ' for the reaction. (R= 8.314 JK^(-1) mol^(-1) )

Rate constant 'k' of a reaction varies with temperature 'T' according to the equation: log K = log A -E_a =(E_a)/(2.303 R) ((1)/(T)) where E_a is the activation energy. When a graph is plotted for log ,k vs (1)/(T ) a straight line with a slope of - 4250 K is obtained. Calculate ‘ E_a ' for the reaction. (R= 8.314 JK^(-1) mol^(-1) )