Concise Physical Chemistry

c07 JWBS043-Rogers September 13, 2010 11:25 Printer Name: Yet to Come

98 EQUILIBRIUM

so ⎡ ⎢ ⎢ ⎣

∂

(

RlnKeq

)

∂

(

1

T

)

⎤

⎥

⎦

p

=−rH◦

whererH◦ is the standard enthalpy of reaction. Now,dT−^1 /dT=−T−^2 and d(1/T)=−T−^2 dT,so

d

(

RlnKeq

)

=−H◦d

(

1

T

)

=

H◦

T^2

dT

This equation can be integrated as

∫ dlnKeq=−

rH◦ R

∫

1

T^2

dT

to give thevan’t Hoff equation

lnKeq=−

rH◦ R

(

−

1

T

)

+const.=

rH◦ R

(

1

T

)

+const.

This is the equation of a straight line of lnKeqplotted against (1/T) withrH◦/R as the slope. It applies so long asrH◦remains constant. The equation as written implies that the slope will be positive, but this does not follow becauserH◦may be positive, negative, or zero for endothermic, exothermic, or null-thermal reactions. Common examples are melting, freezing, or mixing of two isomers of a liquid alkane which are endothermic, exothermic, and null-thermal. The van’t Hoff equation can be integrated between limits to give an expression for a new equilibrium constant at a new temperature from known values ofrH◦,Keq, and the initial and revised temperatures,TandT′:

∫Keq′

Keq

dlnKeq=−

rH◦ R

∫T′

T

1

T^2

dT

ln

Keq′ Keq

=−

rH◦ R

(

1

T′

−

1

T

)

=

rH◦ R

(

1

T

−

1

T′

)

Conversely, the integrated form is a way of determiningrH◦from two experimental determinations ofKeqat different temperatures.

Concise Physical Chemistry

∂

(

)

∂

(

1

T

)

⎤

⎥

⎥

⎦

(

)

(

1

T

)

=

H◦

T^2

∫

1

T^2

(

−

1

T

)

(

1

T

)

∫T′

1

T^2

=−

(

1

T′

−

1

T

)

=

(

1

T

−

1

T′

)

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