1. Design for Energy Efficiency: Design chemical processes that require
minimal energy input to reduce greenhouse gas emissions and improve
energy efficiency.
2. Safer Solvents and Auxiliaries: Use safer solvents and auxiliary substances
in chemical processes to minimize environmental and health risks.
3. Designing Safer Chemicals: Design chemicals with reduced toxicity to
humans and the environment while maintaining their desired functionality.
4. Less Hazardous Chemical Syntheses: Design synthetic routes that
minimize the use of hazardous substances and generate less waste during
production.
5. Atom Economy: Maximize the efficiency of chemical reactions by utilizing
all atoms in the starting materials in the final product, reducing waste
generation.
6. Prevention: Design chemical products and processes to prevent waste
generation, pollution, and environmental harm from the beginning stages.
1. Design with energy efficiency in mind- Include innovative, energy-saving technologies
in process designs. Whenever feasible, choose to power processes with renewable
energy sources. - Put energy recovery and heat exchange process integration strategies
into practice. - To maximize energy use, implement computer-aided process
engineering. Emphasize how combating climate change and lowering carbon footprints
will benefit both.
2. More Secure Ads and Supplements- Determine and encourage the use of solvent
substitutes that pose less of a danger to the environment and public health. Promote
the use of green solvent systems with superior ecological profiles, such as ionic liquids
and supercritical fluids. - Promote the elimination of volatile organic compounds (VOCs),
minimal energy input to reduce greenhouse gas emissions and improve
energy efficiency.
2. Safer Solvents and Auxiliaries: Use safer solvents and auxiliary substances
in chemical processes to minimize environmental and health risks.
3. Designing Safer Chemicals: Design chemicals with reduced toxicity to
humans and the environment while maintaining their desired functionality.
4. Less Hazardous Chemical Syntheses: Design synthetic routes that
minimize the use of hazardous substances and generate less waste during
production.
5. Atom Economy: Maximize the efficiency of chemical reactions by utilizing
all atoms in the starting materials in the final product, reducing waste
generation.
6. Prevention: Design chemical products and processes to prevent waste
generation, pollution, and environmental harm from the beginning stages.
1. Design with energy efficiency in mind- Include innovative, energy-saving technologies
in process designs. Whenever feasible, choose to power processes with renewable
energy sources. - Put energy recovery and heat exchange process integration strategies
into practice. - To maximize energy use, implement computer-aided process
engineering. Emphasize how combating climate change and lowering carbon footprints
will benefit both.
2. More Secure Ads and Supplements- Determine and encourage the use of solvent
substitutes that pose less of a danger to the environment and public health. Promote
the use of green solvent systems with superior ecological profiles, such as ionic liquids
and supercritical fluids. - Promote the elimination of volatile organic compounds (VOCs),
