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In May, campus leaders signed the Green Chemistry Commitment to practice and teach sustainable chemistry—an effort being encouraged and advanced by students

For much of the history of chemistry, the science was done how it was done—with fleeting or no thought given to things like lab energy consumption or the environmental persistence of toxic chemicals used in experiments. Those things were simply considered the wages of scientific progress.

, however, some chemists began asking if there were better, less hazardous, less environmentally damaging ways to do the science. By the 1990s, chemists Paul Anastas and John Warner had given a name to this new approach: green chemistry. In their 1998 book , they detailed the , which include preventing waste rather than trying to treat it or clean it up after the fact and designing chemical products to preserve efficacy of function while reducing toxicity.

Since that time, green chemistry has become a movement as universities and labs around the world evolve the practice and teaching of chemistry to reduce its impact on environmental and human health and safety.

In May, �鶹��Ѱ�����Boulder Chancellor Justin Schwartz and Department of Chemistry Chair Wei Zhang signed the Green Chemistry Commitment, not only committing �鶹��Ѱ�����Boulder to green chemistry in practice and principle but joining a worldwide network of universities working to expand the community of green chemists and affect lasting change in chemistry education.

The �鶹��Ѱ����� has been very involved in the green chemistry movement, and in May Chancellor Justin Schwartz and then-Department of Chemistry Chair Wei Zhang signed the , not only committing �鶹��Ѱ�����Boulder to green chemistry in practice and principle, but joining a worldwide network of universities working to expand the community of green chemists and affect lasting change in chemistry education.

“Signing (the Green Chemistry Commitment) is an important step toward integrating green chemistry into curriculum, theory, toxicology and lab applications,” says Forrest Yegge, chair of the Green Chemistry �鶹��Ѱ�����Student Government (CUSG) Environmental Board subcommittee and a junior studying philosophy and ecology and evolutionary biology.

“Social justice-wise, I think it’s our responsibility to be more aware of the effects we are having on the environment,” adds Jules Immonen, a first-year student studying chemistry who serves as secretary of the CUSG Environmental Board. “Obviously, sustainability is something I’m passionate about, but even people who aren’t should be able to learn how to incorporate these practices in an easy way.”

Doing better chemistry

�鶹��Ѱ�����Boulder’s embrace of green chemistry has been growing for years, says��Kathryn Ramirez-Aguilar, �鶹��Ѱ�����Boulder Green Labs Program manager. The Department of Chemistry and Green Labs have been partnering on��green chemistry efforts on campus, leading initiatives on everything from education opportunities to sustainable lab practices. Signing the Green Chemistry Commitment (GCC) is an important step, Ramirez-Aguilar says: “It’s a huge opportunity to involve students in designing curriculum, and it aligns with CU’s��Climate Action Plan outlined last year.” In fact, she adds, members of the CUSG Environmental Board have been at the vanguard of bringing the GCC to the attention of campus leadership.��

Ashley Ley, a chemistry graduate candidate and member of the Green Chemistry CUSG Environmental Board subcommittee, emphasizes that green chemistry is most importantly about practice, not just theory. “If you look at someone like Dr. (Jacquie) Richardson, she’s been making changes to methods, working toward greener methods using less harmful chemicals in the Organic Chemistry Teaching Labs. In Organic Chemistry 2, there’s a lab focused on atom economy, and one of the previous (Green Labs Chemistry) team leads worked with Dr. Richardson to incorporate acetone recycling, so now organic chemistry teaching labs only use recycled acetone for cleaning.

“These labs have also started using water recirculatory buckets because there are reflux reactions where you need a ton of water and normally it would go through the condensers and down the sink. Now it’s being recirculated, and we’re saving a lot of water. Last summer, they incorporated no-touch doors in the labs [as part of a collaborative project with Green Labs], so you can get in and out of the labs without having to take off your gloves.”

In another campuswide green chemistry application, Amrita George, a professional research assistant of many years in the Department of Integrative Physiology and volunteer lead for the Green Labs Team, is working on introducing a chemical sharing initiative in which research labs share chemicals within their research building.

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Kathryn Ramirez-Aguilar (left), �鶹��Ѱ�����Boulder Green Labs Program manager, and Matt Wise (right), director of chemistry instruction and Department of Chemistry associate chair, give a presentation about incorporating green chemistry into the introductory chemistry curriculum. (Photo: Kathryn Ramirez-Aguilar)

“This has a lot of support from the Environmental Health and Safety group,” George says. “It aligns with one of the principles of green chemistry, which is to reduce the total amount of hazardous chemicals used and, therefore, waste created. [The initiative] allows researchers to see the chemical inventory of other labs within their building and share amongst themselves rather than ordering new stocks for each lab, which is usually what researchers do. Often these stocks sit on the shelf and expire before the lab ever uses them again.”

Ramirez-Aguilar adds that the chemical sharing initiative is also a money saver for labs by reducing purchasing—which also benefits a reduction in carbon emissions similar to a campuswide focus on reducing labs’ energy consumption, as labs are among the most energy-intensive spaces on campus.

Valentina Osorio, a chemistry graduate student and member of the Green Chemistry CUSG Environmental Board subcommittee, adds that General Chemistry teaching faculty have adapted student experiments and lab processes so that they can use drops of a chemical rather than milliliters of it. This makes a significant difference when thousands of students are conducting the experiments each year.

Performing research sustainably

While the benefits of green chemistry practice and teaching are broad and affect many communities and populations, among those most affected are students, says Ana Curry, a chemistry graduate student and member of the Green Chemistry CUSG Environmental Board subcommittee: “I’m currently working in materials chemistry, and I believe strongly that if my research is focused on sustainability, I should also be performing that research sustainably.”

Osorio notes that while her research focus is environmental chemistry, “I’m studying the impacts of air and water pollution, and while I’m not really synthesizing anything, what I’m researching is largely impacted by what humans are doing.”

Yegge adds that in addition to the environmental and social justice benefits of green chemistry, “as I prepare for grad school and I’m increasingly worried about securing funding, I think that sustainable practices on campus and in labs are crucial for resilience in academia and in research. We need to be adopting these strategies so we can keep doing the science we’re doing.”

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