Atomic layer deposition with TiO2for enhanced reactivity and stability of aromatic hydrogenation catalysts

W. Wilson McNeary; Sean A. Tacey; Gabriella D. Lahti; Davis R. Conklin; Kinga A. Unocic; Eric C.D. Tan; Evan C. Wegener; Tugce Eralp Erden; Staci Moulton; Chris Gump; Jessica Burger; Michael B. Griffin; Carrie A. Farberow; Michael J. Watson; Luke Tuxworth; Kurt M. Van Allsburg; Arrelaine A. Dameron; Karen Buechler; Derek R. Vardon

doi:10.1021/acscatal.1c02101

Atomic layer deposition with TiO₂for enhanced reactivity and stability of aromatic hydrogenation catalysts

W. Wilson McNeary, Sean A. Tacey, Gabriella D. Lahti, Davis R. Conklin, Kinga A. Unocic, Eric C.D. Tan, Evan C. Wegener, Tugce Eralp Erden, Staci Moulton, Chris Gump, Jessica Burger, Michael B. Griffin, Carrie A. Farberow, Michael J. Watson, Luke Tuxworth, Kurt M. Van Allsburg, Arrelaine A. Dameron, Karen Buechler, Derek R. Vardon

Materials MicroAnalysis

Research output: Contribution to journal › Article › peer-review

29 Scopus citations

Abstract

Hydrogenation of aromatic molecules in fossil- and bio-derived fuels is essential for decreasing emissions of harmful combustion products and addressing growing concerns around urban air pollution. In this work, we used atomic layer deposition to significantly enhance the hydrogenation performance of a conventional supported Pd catalyst by applying an ultrathin coating of TiO₂in a scalable powder coating process. The TiO₂-coated catalyst showed substantial gains in the conversion of multiple aromatic molecules, including a 5-fold improvement in turnover frequency versus the uncoated catalyst in the hydrogenation of naphthalene. This activity enhancement was maintained upon scaling the coating synthesis process from 3 to 100 g. Based on the results from Xray photoelectron spectroscopy, X-ray absorption spectroscopy, and computational modeling, the activity enhancement was attributed to ensemble effects resulting from partial TiO₂coverage of the Pd surface rather than fundamental changes to the Pd electronic structure. Additional durability testing confirmed that the TiO₂coating improved the thermal and hydrothermal stability of the catalyst as well as tolerance toward sulfur impurities in the reactant stream. Using an economic model of an industrial deep hydrogenation process, we found that an increase in catalyst activity or lifetime of 2× would justify even a relatively high estimate for the cost of TiO₂atomic layer deposition coatings at scale.

Original language	English
Pages (from-to)	8538-8549
Number of pages	12
Journal	ACS Catalysis
Volume	11
DOIs	https://doi.org/10.1021/acscatal.1c02101
State	Published - 2021

Funding

This work was authored in part by Alliance for Sustainable Energy, LLC, the manager and operator of the National Renewable Energy Laboratory (NREL) for the U.S. Department of Energy (DOE) under contract no. DE-AC36- 08GO28308. Funding was provided in part by the U.S. Department of Energy Office of Energy Efficiency and Renewable Energy Bioenergy Technologies Office. This work was partially performed in collaboration with the Chemical Catalysis for Bioenergy Consortium (ChemCatBio), a member of the Energy Materials Network, and was supported by the DOE Bioenergy Technologies Office under contract no. DEAC05- 00OR22725 with Oak Ridge National Laboratory, contract no. DE-AC02-06CH11357 with Argonne National

Keywords

Aromatic hydrogenation
Atomic layer deposition
Catalysts
Coatings
Fuels

Access to Document

10.1021/acscatal.1c02101

Cite this

McNeary, W. W., Tacey, S. A., Lahti, G. D., Conklin, D. R., Unocic, K. A., Tan, E. C. D., Wegener, E. C., Erden, T. E., Moulton, S., Gump, C., Burger, J., Griffin, M. B., Farberow, C. A., Watson, M. J., Tuxworth, L., Van Allsburg, K. M., Dameron, A. A., Buechler, K., & Vardon, D. R. (2021). Atomic layer deposition with TiO₂for enhanced reactivity and stability of aromatic hydrogenation catalysts. ACS Catalysis, 11, 8538-8549. https://doi.org/10.1021/acscatal.1c02101

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title = "Atomic layer deposition with TiO2for enhanced reactivity and stability of aromatic hydrogenation catalysts",

abstract = "Hydrogenation of aromatic molecules in fossil- and bio-derived fuels is essential for decreasing emissions of harmful combustion products and addressing growing concerns around urban air pollution. In this work, we used atomic layer deposition to significantly enhance the hydrogenation performance of a conventional supported Pd catalyst by applying an ultrathin coating of TiO2in a scalable powder coating process. The TiO2-coated catalyst showed substantial gains in the conversion of multiple aromatic molecules, including a 5-fold improvement in turnover frequency versus the uncoated catalyst in the hydrogenation of naphthalene. This activity enhancement was maintained upon scaling the coating synthesis process from 3 to 100 g. Based on the results from Xray photoelectron spectroscopy, X-ray absorption spectroscopy, and computational modeling, the activity enhancement was attributed to ensemble effects resulting from partial TiO2coverage of the Pd surface rather than fundamental changes to the Pd electronic structure. Additional durability testing confirmed that the TiO2coating improved the thermal and hydrothermal stability of the catalyst as well as tolerance toward sulfur impurities in the reactant stream. Using an economic model of an industrial deep hydrogenation process, we found that an increase in catalyst activity or lifetime of 2× would justify even a relatively high estimate for the cost of TiO2atomic layer deposition coatings at scale.",

keywords = "Aromatic hydrogenation, Atomic layer deposition, Catalysts, Coatings, Fuels",

author = "McNeary, {W. Wilson} and Tacey, {Sean A.} and Lahti, {Gabriella D.} and Conklin, {Davis R.} and Unocic, {Kinga A.} and Tan, {Eric C.D.} and Wegener, {Evan C.} and Erden, {Tugce Eralp} and Staci Moulton and Chris Gump and Jessica Burger and Griffin, {Michael B.} and Farberow, {Carrie A.} and Watson, {Michael J.} and Luke Tuxworth and {Van Allsburg}, {Kurt M.} and Dameron, {Arrelaine A.} and Karen Buechler and Vardon, {Derek R.}",

year = "2021",

doi = "10.1021/acscatal.1c02101",

language = "English",

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McNeary, WW, Tacey, SA, Lahti, GD, Conklin, DR, Unocic, KA, Tan, ECD, Wegener, EC, Erden, TE, Moulton, S, Gump, C, Burger, J, Griffin, MB, Farberow, CA, Watson, MJ, Tuxworth, L, Van Allsburg, KM, Dameron, AA, Buechler, K & Vardon, DR 2021, 'Atomic layer deposition with TiO₂for enhanced reactivity and stability of aromatic hydrogenation catalysts', ACS Catalysis, vol. 11, pp. 8538-8549. https://doi.org/10.1021/acscatal.1c02101

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T1 - Atomic layer deposition with TiO2for enhanced reactivity and stability of aromatic hydrogenation catalysts

AU - McNeary, W. Wilson

AU - Tacey, Sean A.

AU - Lahti, Gabriella D.

AU - Conklin, Davis R.

AU - Unocic, Kinga A.

AU - Tan, Eric C.D.

AU - Wegener, Evan C.

AU - Erden, Tugce Eralp

AU - Moulton, Staci

AU - Gump, Chris

AU - Burger, Jessica

AU - Griffin, Michael B.

AU - Farberow, Carrie A.

AU - Watson, Michael J.

AU - Tuxworth, Luke

AU - Van Allsburg, Kurt M.

AU - Dameron, Arrelaine A.

AU - Buechler, Karen

AU - Vardon, Derek R.

PY - 2021

Y1 - 2021

N2 - Hydrogenation of aromatic molecules in fossil- and bio-derived fuels is essential for decreasing emissions of harmful combustion products and addressing growing concerns around urban air pollution. In this work, we used atomic layer deposition to significantly enhance the hydrogenation performance of a conventional supported Pd catalyst by applying an ultrathin coating of TiO2in a scalable powder coating process. The TiO2-coated catalyst showed substantial gains in the conversion of multiple aromatic molecules, including a 5-fold improvement in turnover frequency versus the uncoated catalyst in the hydrogenation of naphthalene. This activity enhancement was maintained upon scaling the coating synthesis process from 3 to 100 g. Based on the results from Xray photoelectron spectroscopy, X-ray absorption spectroscopy, and computational modeling, the activity enhancement was attributed to ensemble effects resulting from partial TiO2coverage of the Pd surface rather than fundamental changes to the Pd electronic structure. Additional durability testing confirmed that the TiO2coating improved the thermal and hydrothermal stability of the catalyst as well as tolerance toward sulfur impurities in the reactant stream. Using an economic model of an industrial deep hydrogenation process, we found that an increase in catalyst activity or lifetime of 2× would justify even a relatively high estimate for the cost of TiO2atomic layer deposition coatings at scale.

AB - Hydrogenation of aromatic molecules in fossil- and bio-derived fuels is essential for decreasing emissions of harmful combustion products and addressing growing concerns around urban air pollution. In this work, we used atomic layer deposition to significantly enhance the hydrogenation performance of a conventional supported Pd catalyst by applying an ultrathin coating of TiO2in a scalable powder coating process. The TiO2-coated catalyst showed substantial gains in the conversion of multiple aromatic molecules, including a 5-fold improvement in turnover frequency versus the uncoated catalyst in the hydrogenation of naphthalene. This activity enhancement was maintained upon scaling the coating synthesis process from 3 to 100 g. Based on the results from Xray photoelectron spectroscopy, X-ray absorption spectroscopy, and computational modeling, the activity enhancement was attributed to ensemble effects resulting from partial TiO2coverage of the Pd surface rather than fundamental changes to the Pd electronic structure. Additional durability testing confirmed that the TiO2coating improved the thermal and hydrothermal stability of the catalyst as well as tolerance toward sulfur impurities in the reactant stream. Using an economic model of an industrial deep hydrogenation process, we found that an increase in catalyst activity or lifetime of 2× would justify even a relatively high estimate for the cost of TiO2atomic layer deposition coatings at scale.

KW - Aromatic hydrogenation

KW - Atomic layer deposition

KW - Catalysts

KW - Coatings

KW - Fuels

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