Research | Notestein Research Group

Our Research

For the most up-to-date examples of our research, check out our Publications page.

For a sample of some of our many projects, keep reading!

Metal-Organic Frameworks (MOFs) as Heterogeneous Catalysts and Supports

MOFs offer the potential for uniform distributions of isolated catalytic active sites that can be compared to conventional supported catalysts.
MOFs also offer a broader range of control over the local pore environment than do zeolites or conventional oxide supports. This can have an especially important role for condensed phase reactions.
Currently, we use probe reactions such as non-oxidative ethanol dehydrogenation, butene hydrogenation and isomerization to understand the nature of isolated catalytic active sites in MOF systems.

Bulk oxides can be used as catalysts and supports, and their structures play an important role in dictating reactivity.
We have extensive work on ceria-based materials, including different nanoshapes, clusters, and 2D materials.
We have also worked to understand how additional active sites (VOx, FeOx, CoOx) are grafted onto these redox-active solids.
Through collaboration, we have examine novel lanthanide scandates and metal titanates as catalyst supports.

We are developing new shape-selective, all-oxide catalysts that we call nanobowls. We are learning to control size, shape, and even chirality.
These materials consist of < 2 nm cavities on the surface of an oxide carrier particle that exists as controlled voids in an overcoated layer. They may be of a variety of compositions.
The overcoating concept is being extended to control selectivity and improve stability of a number of catalyst classes including supported metal nanoparticles, acid catalysts, and tandem catalysts.
Variations include developing novel methods to entrench or to overcoat active sites in collaboration with other research groups.

Selective ring-opening of epoxides leads to a number of useful products or synthons and is a useful probe reaction for understanding acid catalysts.
We use computational techniques and experimental data to develop homogeneous and heterogeneous regioselective catalysts and to optimize reaction conditions.

Combining thermocatalysis with other catalytic modalities (photocatalysis, electrocatalysis, biocatalysis) offers many new and exciting opportunities
Microbial electrosynthesis cells can use a variety of species in wastewater to produce dilute aqueous H2O2, which can be utilized by a thermocatalyst operated for downstream chemicals production.
Photocatalysts or photochemical initiation can generate reactive intermediates that react further on conventional thermocatalytic sites.

We have shown them to be active for alkane dehydrogenation and alcohol dehydrogenation and acceptor-less dehydrogenative coupling
Metal sulfides are much less studied for dehydrogenation.
Metal sulfides are known hydrogen evolution catalysts and are used frequently in hydrogenation/hydrogenolysis (hydrotreating)

We are also learning to understand support effects via Lewis acidity dye probes.
At low loadings, it is an active material for oxidative dehydrogenation with significant support effects and differences from other supported oxides
Supported copper oxide is often inactive or is prone to complete reduction to metal at high loadings

Metal oxide catalysts including zeolites (SiO2-Al2O3) usually contain a mixture of sites and pore structures
Targeted catalyst design is in high demand for application in natural gas and biomass conversion processes
NRG has developed a liquid phase SiO2 overcoat technology and applied this to Al2O3 and Ti-SiO2 catalysts

Professor Justin Notestein

2145 Sheridan Road

Tech E250

Evanston, IL 60208-3109