E-factor
Contributors
Summary
E-factor is a metric that measures the overall efficiency in terms of waste generation of a chemical reaction. E-factor stands for the "Environmental Impact Factor" and is the ratio of how much waste is produced per unit of product made:
E factor= (mass of waste produced (g))/(mass of isolated product (g))
As a result, the lower the E-factor, the more sustainable and less wasteful the reaction is (with the lowest possible value being zero). This is a metric commonly used in industrial settings and a skill that can be applied to other labs done in your classroom.
In lab settings, students can apply the concept of E-factor to evaluate the efficiency of chemical reactions they perform. E-factor is an important concept in green chemistry because it encourages students to think about the environmental impact of chemical reactions and promotes the development of sustainable chemical processes. E-Factor relates to other green chemistry metrics including the 2nd Principle of Green Chemistry, Atom Economy.
E factor= (mass of waste produced (g))/(mass of isolated product (g))
As a result, the lower the E-factor, the more sustainable and less wasteful the reaction is (with the lowest possible value being zero). This is a metric commonly used in industrial settings and a skill that can be applied to other labs done in your classroom.
In lab settings, students can apply the concept of E-factor to evaluate the efficiency of chemical reactions they perform. E-factor is an important concept in green chemistry because it encourages students to think about the environmental impact of chemical reactions and promotes the development of sustainable chemical processes. E-Factor relates to other green chemistry metrics including the 2nd Principle of Green Chemistry, Atom Economy.
Safety Precautions, Hazards, and Risk Assessment
Do not allow students to eat food materials that come in contact with any lab equipment or contaminated surfaces.
Teacher Recommendations or Piloting Data (if available)
Use the bulk bag of M&M’S to prepare five baggies of M&M’S as shown in the table below. The green M&Ms represent a unit of mass of the desired product, whereas all other colored M&Ms represent the waste. Baggies of M&M’s do not need to be precise ratios, but should range in the ratio of green M&M’s to other colored M&M’s. For example, one bag should look similar to the exemplar in the table next to petrochemicals with a composition being mostly green M&M’s, while another bag modeling pharmaceuticals should only have approximately one green M&M in it.
Bag C Ratio: 10 green: 1 non-green
Bag B Ratio: 1 green: 4 non-green
Bag A: 1 green: 20 non-green
Bag D:1 green: 250 non-green
Bag C Ratio: 10 green: 1 non-green
Bag B Ratio: 1 green: 4 non-green
Bag A: 1 green: 20 non-green
Bag D:1 green: 250 non-green
Digital Object Identifier (DOI)
https://doi.org/10.59877/EGLM5581
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