Difference between revisions of "Catalysis:Problems:Problem 1"

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1. Determine the dependence of the rate of reaction (CO<sub>2</sub> production) on the concentrations of the reactants (reaction orders) for isothermal catalytic CO oxidation at 600 K on catalyst A.  To help discern the concentration effects, it may be useful to graph the rate of CO<sub>2</sub> production vs. each species’ concentration. Propose a catalytic rate law (not just a power law model) for this system.  To accomplish this task, you will need to have reaction rate information, which can come from an analysis of real-time simulation data (one option is the method of initial rates[ref]).  Determine rate and equilibrium constants for you proposed rate law for the given catalyst A system at 600 K, using the data collected.
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1. Determine the dependence of the rate of reaction (CO<sub>2</sub> production) on the concentrations of the reactants (reaction orders) for isothermal catalytic CO oxidation at 600 K on catalyst A.  To help discern the concentration effects, it may be useful to graph the rate of CO<sub>2</sub> production vs. each species’ concentration. Propose a catalytic rate law (not just a power law model) for this system.  To accomplish this task, you will need to have [[Catalysis:Determination of Rate Law Parameters|reaction rate information]], which can come from an analysis of real-time simulation data (see [[Catalysis:References|Fogler or Laidler]]).  [[Catalysis:Determination of Rate Law Parameters|Determine rate and equilibrium constants]] for you proposed rate law for the given catalyst A system at 600 K, using the data collected.

Latest revision as of 22:20, 15 July 2010

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1. Determine the dependence of the rate of reaction (CO2 production) on the concentrations of the reactants (reaction orders) for isothermal catalytic CO oxidation at 600 K on catalyst A. To help discern the concentration effects, it may be useful to graph the rate of CO2 production vs. each species’ concentration. Propose a catalytic rate law (not just a power law model) for this system. To accomplish this task, you will need to have reaction rate information, which can come from an analysis of real-time simulation data (see Fogler or Laidler). Determine rate and equilibrium constants for you proposed rate law for the given catalyst A system at 600 K, using the data collected.