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Chapter 18: Problem 47

One of the principles of green chemistry is that it is better to use as few steps as possible in making new chemicals. How does this principle relate to energy efficiency?

Short Answer

Expert verified
Reducing the number of steps in a chemical process improves energy efficiency, a key aspect of green chemistry. Fewer steps require less energy for heating, cooling, and powering equipment used in each step, and minimize the need for energy-consuming purification and separation processes. This results in energy and resource conservation, decreased pollution, and lower overall production costs. For example, if aspirin synthesis were to be streamlined into a single step, energy efficiency would be improved, reducing its environmental impact.

Step by step solution

01

Introduction to Green Chemistry

Green chemistry, also known as sustainable chemistry, is a set of principles focused on designing products and processes that minimize the use and generation of hazardous substances. Green chemistry aims to reduce the environmental impact of the chemical industry by making it more efficient and sustainable.
02

Energy Efficiency in Chemical Processes

Energy efficiency is an essential aspect of green chemistry. It refers to the amount of useful output (chemical products) created per unit of energy input. The higher the energy efficiency, the less energy is wasted during the process. Energy efficiency is important as it helps to conserve valuable resources, reduce pollution from energy production, and decrease the overall cost of production.
03

Reducing Steps and Energy Efficiency

Reducing the number of steps in a chemical process can improve its energy efficiency. When a chemical process has fewer steps, less energy is required for heating, cooling, and powering the equipment used in each step. Moreover, each step in a chemical process may require separate purification and separation processes, which also consume energy. So, by minimizing the number of steps, we can save energy, reduce waste, and improve the overall sustainability of the process.
04

Example: Synthesis of Aspirin

Let's consider the synthesis of aspirin as an example. Traditionally, aspirin synthesis involves two steps: (1) acetylation of salicylic acid with acetic anhydride to produce acetylsalicylic acid (aspirin) and (2) precipitation of aspirin from the reaction mixture. If a greener method were to be developed that combined these two steps into a single step, the energy efficiency would be improved. Less energy would be needed for heating, cooling, and separating the products, as well as for cleaning the equipment between steps. As a result, the overall environmental impact of aspirin production would be reduced.

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