A. It lowers activation energy for both directions.B. It changes the equilibrium constant.C. It helps equilibrium be reached faster.D. It does not change the equilibrium composition.
Correct Answer: A|C|D
Explanation:
A catalyst changes rates, not thermodynamic equilibrium.
A. It lowers activation energy for both directions.B. It changes the equilibrium constant.C. It helps equilibrium be reached faster.D. It does not change the equilibrium composition.
Correct Answer: A|C|D
Explanation:
A catalyst changes rates, not thermodynamic equilibrium.
A. It lowers activation energy for both directions.B. It changes the equilibrium constant.C. It helps equilibrium be reached faster.D. It does not change the equilibrium composition.
Correct Answer: A|C|D
Explanation:
A catalyst changes rates, not thermodynamic equilibrium.
A. It lowers activation energy for both directions.B. It changes the equilibrium constant.C. It helps equilibrium be reached faster.D. It does not change the equilibrium composition.
Correct Answer: A|C|D
Explanation:
A catalyst changes rates, not thermodynamic equilibrium.
A. It lowers activation energy for both directions.B. It changes the equilibrium constant.C. It helps equilibrium be reached faster.D. It does not change the equilibrium composition.
Correct Answer: A|C|D
Explanation:
A catalyst changes rates, not thermodynamic equilibrium.
A. Internal energy depends only on temperature.B. At constant temperature, PV is constant for fixed amount of gas.C. Molecules have significant intermolecular potential energy.D. The average translational kinetic energy rises with absolute temperature.
Correct Answer: A|B|D
Explanation:
The ideal-gas model neglects intermolecular potential energy.
A. It lowers activation energy for both directions.B. It changes the equilibrium constant.C. It helps equilibrium be reached faster.D. It does not change the equilibrium composition.
Correct Answer: A|C|D
Explanation:
A catalyst changes rates, not thermodynamic equilibrium.
A. Internal energy depends only on temperature.B. At constant temperature, PV is constant for fixed amount of gas.C. Molecules have significant intermolecular potential energy.D. The average translational kinetic energy rises with absolute temperature.
Correct Answer: A|B|D
Explanation:
The ideal-gas model neglects intermolecular potential energy.
A. It lowers activation energy for both directions.B. It changes the equilibrium constant.C. It helps equilibrium be reached faster.D. It does not change the equilibrium composition.
Correct Answer: A|C|D
Explanation:
A catalyst changes rates, not thermodynamic equilibrium.