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What tricks can organic molecules be taught to help solve our planet's biggest problems? That's the question driving Assistant Professor Richard Y. Liu as he pushes the frontiers of organic chemistry in pursuit of cleaner synthesis, smarter materials, and new ways to combat climate change.

Liu's latest advance, detailed in a new paper in , harnesses the power of sunshine to trigger a particular variety of organic molecule. As described in the paper, these "photobases" then rapidly generate hydroxide ions that efficiently and reversibly trap CO₂.

This innovation in direct air capture marks a significant step toward scalable, low-energy solutions for removing greenhouse gases, Liu said. "What distinguishes this current work is the way we developed molecular switches to capture and release CO₂ with light. The general strategy of using light directly as the energy source is a new approach."

Liu's drive to understand the inner workings of organic chemistry dates to his years at Harvard College. "I started out thinking I'd be a physicist," he said. "But in my first semester, I realized I was much more captivated by the creative act of building molecules in the chemistry lab."

Under the guidance of Ted Betley, Erving Professor of Chemistry, Liu uncovered a passion for organic synthesis, or designing and assembling complex structures atom by atom.

"My mentor noticed that what really excited me wasn't the iron complexes we were supposed to be working on," Liu said. "It was the challenge of making the organic ligands themselves."

Betley encouraged Liu to pursue these interests by working with a group led by Eric Jacobsen, Sheldon Emery Professor of Chemistry. There, Liu learned to think about molecules in new ways, to ask big questions, and to take big risks.

That ethos remained central during his doctoral work at the Massachusetts Institute of Technology, where Liu worked with chemist Stephen Buchwald to invent new copper and palladium catalysts that allow complex molecules to be prepared from convenient and readily available building blocks.

Now leading his own lab in the Department of Chemistry and Chemical Biology, Liu focuses on issues spanning the fields of organic, inorganic, and materials chemistry. His group's research centers on organic redox platforms, metal-based catalysts for synthesis, and mechanistic studies that reveal how chemical transformations unfold.

"We're looking at how to manipulate nonmetals—in molecules that are cheap, abundant, and tunable—to do chemistry traditionally reserved for metals," Liu said.

Their work isn't just theoretical; it's built for the real world. Liu's group is also developing new organic materials for energy storage and catalysis, as well as molecules that can capture and activate greenhouse gases. The recent direct air capture development was the product of a collaboration with Daniel G. Nocera, Patterson Rockwood Professor of Energy, and exemplifies the Liu lab's pursuit of applicable solutions.

"Direct air capture is one of the most important emerging climate technologies, but existing methods require too much energy," he said.

"By designing molecules that use light to change their chemical state and trap CO₂, we're demonstrating a path to a more efficient—and possibly solar-powered—future."

Also responsible for the discovery is the lab's interdisciplinary team of chemists, materials scientists, and engineers.

"We all speak the language of organic synthesis, but each person has an area of deeper expertise—from electrochemistry to sulfur chemistry to computational modeling," Liu said. "This means we are able to generate new ideas at the intersections."

Educating the next generation of scientists is core to that mission, he added. "Ultimately, the research we do here is kind of a platform for training and education," Liu said.

"The projects we do are ultimately for students to have a compelling and complete thesis that earns them their Ph.D. and serves as a springboard for what they're going to do in the future."

Yet the recent disruptions in federal funding present what Liu calls "an existential threat."

"Research done at universities and institutions of higher learning will ultimately reap profits for all of society," Liu said. "Our research is not driven by profits, but meant to make our discoveries and advancements publicly available for the world's benefit."

This story is published courtesy of the , Harvard University's official newspaper. For additional university news, visit .