Using the initial partial pressures of H 2 O , CO , and H 2 we can find their equilibrium partial pressures at 1000 K for the reaction C ( g ) + H 2 O ( g ) ⇌ C O ( g ) + H 2 ( g ) . Concept introduction: Partial Pressure is defined as the pressure an individual gas exerts. It is independent of other gases that may be present in a mixture. According to the ideal gas law , partial pressure is inversely proportional to volume. It is also directly proportional to moles and temperature. Given: The initial partial pressures of P C O =1.00 atm and P H 2 =1.40 atm. The equilibrium constant K p for the reaction is C ( g ) + H 2 O ( g ) ⇌ C O ( g ) + H 2 ( g ) 2.44 at 1000 K. To determine: The equilibrium partial pressures of H 2 O , CO , and H 2 at 1000 K for the reaction C ( g ) + H 2 O ( g ) ⇌ C O ( g ) + H 2 ( g )

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Chapter 14, Problem 14.21P

Interpretation Introduction

Interpretation:

Using the initial partial pressures of H2O , CO , and H2 we can find their equilibrium partial pressures at 1000 K for the reaction C(g)+H2O(g)⇌CO(g)+H2(g) .

Concept introduction:

Partial Pressure is defined as the pressure an individual gas exerts. It is independent of other gases that may be present in a mixture. According to the ideal gas law, partial pressure is inversely proportional to volume. It is also directly proportional to moles and temperature.

Given:

The initial partial pressures of P_C_O=1.00 atm and P_H₂=1.40 atm.

The equilibrium constant K_p for the reaction is C(g)+H2O(g)⇌CO(g)+H2(g) 2.44 at 1000 K.

To determine:

The equilibrium partial pressures of H2O , CO , and H2 at 1000 K for the reaction C(g)+H2O(g)⇌CO(g)+H2(g)

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