5 Must Know Facts For Your Next Test

1. Active sites can vary in number and accessibility depending on the catalyst's physical and chemical properties, which impacts overall reaction efficiency.
2. The strength of adsorption at active sites influences the activation energy of the reactions taking place, thereby affecting reaction rates.
3. Different types of catalysts may exhibit distinct active sites, leading to varying selectivities for particular products during surface reactions.
4. Temperature and pressure can alter the characteristics of active sites, which may enhance or inhibit catalytic activity.
5. Poisoning of active sites by impurities can significantly decrease a catalyst's performance, making the management of reaction conditions essential.

Review Questions

• How do the characteristics of active sites impact the efficiency of catalysis?
  • The characteristics of active sites, such as their size, shape, and electronic properties, directly influence how well reactants can adsorb and undergo reaction on a catalyst's surface. If the active sites are well-suited for the reactants, they will have a higher likelihood of facilitating efficient surface reactions. Conversely, poorly matched active sites can lead to slower reaction rates and lower overall catalytic efficiency.
• Discuss the relationship between active sites and adsorption in surface reactions.
  • Active sites are where adsorption occurs, making them integral to surface reactions. When reactants adsorb onto these active sites, they become positioned for reaction to take place. The strength and nature of this adsorption influence how readily reactants interact with each other at the active site. Understanding this relationship helps in designing better catalysts by optimizing the properties of active sites to improve adsorption behavior and reaction rates.
• Evaluate how temperature variations can affect the activity of active sites in catalytic processes.
  • Temperature variations can significantly impact the activity of active sites by altering both the kinetic energy of molecules and the properties of the catalyst itself. Higher temperatures generally increase molecular movement, enhancing adsorption rates at active sites; however, they can also lead to desorption if the energy exceeds binding energy. Conversely, lower temperatures might slow down reaction rates due to reduced kinetic energy. Hence, balancing temperature is crucial for maximizing catalytic activity while maintaining stability of the active sites.

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