Publications

W. K. Guo, E. Rosko, G. Zeszutek, U. DeVore, X. Zhang, M. J. Janik, G. Noh. Ind. Eng. Chem. Res., 2024, 63, 6325-6332.

J. Lucas, N. S. P. Naveen, M. J. Janik, K. Alexopoulos, G. Noh, D. Aireddy, K. Ding, J. A. Dorman, K. M. Dooley. ACS Catalysis, 2024, 14, 9115-9133.

C. W. Pester,* G. Noh,* A. Fu. ACS Polymers Au, 2023, 3, 295-306.

14. Hu, W., Noh, G., Iglesia, E. “Consequences of metal-acid site proximity for alkane isomerization and β-scission mediated by bifunctional catalytic cascades.Journal of Catalysis. 2023, 425, 125-142.


13. Sot, P., Noh, G., Weber, I.C., Pratsinis, S. E., Copéret, C. "The Influence of ZnO-ZrO2 Interface in Hydrogenation of CO2 to CH3OH." Helvetica Chimica Acta, 2022, 3, e202200007.


12. Invited perspective for Boudart special issue. Noh, G.,* Sarazen, M. L.* "Transport in heterogeneous catalysis--Beyond reactant diffusion limitations." Journal of Catalysis, 2021, 404, 679-686.


11. Meyet, J., Ashuiev, A., Noh, G., Newton, M. A., Klose, D., Searles, K. F., van Bavel, A. P., Horton, A. D., Jeschke, G., van Bokhoven, J. A., Copéret, C. “CH4-to-CH3OH on Mononuclear Cu(II) Sites Supported on Al2O3: Structure of Active Sites from EPR.Angewandte Chemie International Edition, 2021, 60, 16200-16207.


10. Docherty, S. R., Phongprueksathat, N., Lam, E., Noh, G., Safonova, O., Atsushi, A., Copéret, C. “Silica-supported PdGa Nanoparticles: Metal Synergy for Highly Active and Selective CO2-to-CH3OH Hydrogenation.JACS Au, 2021, 1, 450-458.


09. Noh, G., Lam, E., Bregante, D. T., Meyet, J., Šot, P., Flaherty, D. W., Copéret, C. “Lewis Acid Strength of Interfacial Metal Sites Drives CH3OH Selectivity and Formation Rates on Cu-based CO2 Hydrogenation Catalysts.Angewandte Chemie International Edition, 2021, 60, 9650-9659.


08. Lam, E., Noh, G., Larmier, K., Safonova, O., Copéret, C. “CO2 Hydrogenation on Cu-Catalysts Generated from ZnII Single-Sites: Enhanced CH3OH Selectivity Compared to Cu/ZnO/Al2O3.Journal of Catalysis, 2021, 394, 266-272.


07. Lam, E., Noh, G., Chan, K. W., Larmier, K., Lebedev, D., Searles, K., Wolf, P., Safonova, O., Copéret, C. “Enhanced CH3OH Selectivity in CO2 Hydrogenation using Cu-based Catalysts Generated via SOMC from GaIII Single-Sites.Chemical Science, 2020, 11, 7593-7598.


06. Noh, G., Docherty, S. R., Lam, E., Huang, X., Mance, D., Alfke, J. A., Copéret, C. “CO2 Hydrogenation to CH3OH on Supported Cu Nanoparticles: Nature and Role of Ti in Bulk Oxides vs. as Isolated Surface Sites.Journal of Physical Chemistry C., 2019, 123 (51), 31082-31093.


05. Lam, E., Corral, J. J. P., Larmier, K., Noh, G., Wolf, P., Urakawa, A., Copéret, C. “CO2 Hydrogenation on Cu/Al2O3: Role of Metal/Support Interface in Driving Activity and Selectivity of a Bifunctional Catalyst.Angewandte Chemie International Edition, 2019, 58 (39), 13989-13996.


04. Noh, G., Zones, S. I., Iglesia, E. “Isomer sieving and the selective formation of terminal methyl branches in reactions of linear alkanes on one-dimensional zeolites.Journal of Catalysis. 2019, 377, 255-270.


03. Noh, G., Lam, E., Alfke, J. A., Larmier, K., Searles, K., Wolf, P., Copéret, C. “Selective hydrogenation of CO2 to CH3OH on supported Cu nanoparticles promoted by isolated TiIV surface sites on SiO2.ChemSusChem, 2019, 11, 968-972.


02. Noh, G., Zones, S. I., Iglesia, E. “Consequences of acid strength and diffusional constraints for alkane isomerization and β-scission turnover rates and selectivities on bifunctional metal-acid catalysts.Journal of Physical Chemistry C, 2018, 122 (44), 25475-25497.


01. Noh, G., Shi. Z., Zones, S. I., Iglesia, E. “Isomerization and β-scission reactions of alkanes on bifunctional metal-acid catalysts: Consequences of confinement and diffusional constraints on reactivity and selectivity.Journal of Catalysis, 2018, 368, 389-410.