UCLA assistant professor of chemistry, Chong Liu, has been named by Science News as one of 10 exceptional young scientists.
Prior to joining the UCLA faculty in July 2017, Liu worked with working with Prof. Daniel Nocera at Harvard University as a Lee Kuan Yew postdoctoral fellow. At Harvard he combined the strengths of biology and inorganic chemistry, and developed inorganic/bio hybrid systems of solar-driven CO2 and N2 fixation with the efficiencies higher than natural counterparts. In 2016, this work was published in Science of which Liu was the co-first author.
Liu received his B.S. degree in chemistry from Fudan University, China, where he synthesized mesoporous materials with Prof. Dongyuan Zhao. He then pursued his graduate research at University of California, Berkeley, working with Prof. Peidong Yang.
Liu’s group has specific interests in electrochemical systems for energy, biology, and environments. Combining their expertise in inorganic chemistry, nanomaterials, and electrochemistry, his group aims to address some of the challenging questions in catalysis, energy conversion, CO2/N2 fixation, and microbiota.
To learn more about Liu’s research, visit his group’s website.
From UCLA Newsroom (by Stuart Wolpert):
Chemist named one of 10 exceptional young scientists by Science News
UCLA chemist Chong Liu’s approach to artificial photosynthesis may one day be useful in places without extensive energy infrastructure, Science News said. Penny Jennings/UCLA
Chong Liu, UCLA assistant professor of chemistry, has been named by Science News this week as one of 10 Scientists to Watch. Science News selected exceptional scientists age 40 and younger who are “ready to transform their fields,” “stand out to mentors and peers as people who will make a difference,” are “creative, curious and fearless” and “share a willingness to question existing knowledge and forge new paths.”
Science News said Liu, 30, tackles big and challenging problems. He was among the first scientists to combine bacteria with metals or other inorganic materials to replicate the energy-generating chemical reactions of photosynthesis. Liu’s approach to artificial photosynthesis may one day be especially useful in places without extensive energy infrastructure, Science News said.
Liu majored in chemistry at Fudan University in Shanghai, and according to Science News, was frustrated when he would ask questions and be told that the answer was beyond the scope of what he needed to know.
Photosynthesis is powerful, but has room for improvement; plant converts only one percent of solar energy into chemical energy. Liu thought he could do better.
He and colleagues designed artificial “leaves” to collect solar energy and generate electric current. The current splits water molecules into oxygen and hydrogen, and bacteria in the water transform carbon dioxide and hydrogen into fuels or other useful chemicals.
His research team reported in the journal Science in 2016, a device that was about 10 times as efficient as plants at removing carbon dioxide from the air.
In one of his research projects, Liu is studying the way the inorganic components of soil influence bacteria’s ability to run important chemical reactions. He wants to understand the relationship between soil and microbes.
His laboratory combines expertise in inorganic chemistry, nanomaterials and electrochemistry, to address challenging questions in such areas as catalysis, energy conversion and other environmental applications, as well as biological applications.