Resnick Institute Seminar
Research talks from Resnick Graduate Research Fellow Bryan Hunter & Postdoctoral Scholar Zhu Liu Ph.D.
Please join us!
Bryan Hunter | Splitting Water with Iron for Solar Fuel
Our ability to utilize sustainable resources will be critical in meeting the ever-increasing global energy demand in an eco-friendly manner. The most reliable and available source of sustainable energy is the sun. As a consequence, we must find a way to convert solar energy into storable, transportable fuels. Earth-abundant, efficient, and robust water oxidation catalysts need to be rationally designed based on their catalytic mechanisms.
We recently reported [NiFe]-LDH (layered double hydroxide) nanocatalyst materials that are highly active for water oxidation. We have employed novel in-situ spectroelectrochemistry techniques to identify short-lived catalytic intermediates in nonaqueous media. In particular, we find strong evidence for an iron(VI) oxo that likely plays a role in water oxidation.
Based on the proposed structures of these trapped intermediates, we have developed new catalytic reaction schemes for the [NiFe]-LDH material. Looking forward, we hope to utilize this scalable, earth-abundant material for other important transformations, such as the sustainable oxidation of hydrocarbons.
Zhu Liu Ph.D. | Revisiting Anthropogenic Carbon Emissions
Anthropogenic carbon emissions come mainly from fossil fuel combustion and cement production process are generally considered to be precisely estimated with limited uncertainty. However, rapid emission growth from emerging economies has introduced new errors in global carbon emission estimations. We implemented in situ measurements and bottom up investigation on the carbon emissions in China, and our new results show the emissions could be 15% lower than previously estimated, with considerable uncertainty. This results in 5% less human induced carbon emissions than found in the current literature. We also observed the carbon uptake effect by cement materials, and quantified the global carbon uptake by cement carbonation. The results show that during 1930-2010, the carbon uptake of cement materials is globally equivalent to about half of the total emissions that are produced during cement production. Our results contribute to the understanding of human impact on global carbon cycles.
Refreshments in the Guggenheim Lobby before the seminar starting at 2:45 pm!