Publication

Journal Articles

2025

[21] Y. Kim1*, D. H. Kim*, "Support-Dependent Formic Acid Dehydrogenation over Pd-Supported Catalysts Induced by Hydrogen Spillover" Energy & Fuels, 2025, 39, 34, 16399–16406.

Before Gachon University

2024

[20] Y. Kim1, J. Lee, A. Krishnan, J. Luo, X. Chen, F. M. Alamgir, D. W. Flaherty*, “Formation of Acetonitrile and Ethylene from Activation of Ethane over Cobalt-Exchanged Aluminosilicates: Active Sites and Reaction Pathways” Applied Catalysis B: Environment and Energy, 2024, 359, 124513.

2023

[19] Y. Kim1, J. Kim, M. H. Wiebenga, S. H. Oh, and D. H. Kim*, “Abatement of photochemical smog precursors through complete hydrocarbon oxidation over commercial Pd catalysts under fuel-lean conditions with NO promoting effect”, Environmental Pollution, 2023, 338, 122721.

[18] Y. Kim1, and D. H. Kim*, “Elucidating the alloying effect of PdAg/CNT catalysts on formic acid dehydrogenation with kinetic isotope effect”, Molecular Catalysis, 2023, 547, 113343.

[17] J. Kirk1, Y. Kim1, Y.-J. Lee1, M. Kim, D.-S. Min, P. S. Kim, J. H. Seo, Y. Kim, J. Lee, J. W. Choung, H. Sohn, S.-W. Nam, C.-W. Yoon, Y. Kim, H. Jeong “Pushing the limits of sodium borohydride hydrolysis for on-board hydrogen generation systems” Chemical Engineering Journal, 2023, 446, 143233.

[16] Y. Kim1, G. Jang, D. H. Kim*, “Hydrogen Production via Cerium-Promoted Dehydrogenation of Formic Acid Catalyzed by Carbon-Supported Palladium Nanoparticles”, ACS Applied Nano Materials, 2023, 6, 6929-6939.

2022

[15] A. Badakhsh1, D. Song, S. Moon, H. Jeong, H. Sohn, S. W. Nam, P. S. Kim, J. H. Seo, Y. Kim, J. Lee, J. W. Choung, Y. Kim “COX-free LOHC dehydrogenation in a heatpipe reformer highly integrated with a hydrogen burner” Chemical Engineering Journal, 2022, 449, 137679.

[14] J. Lee1, Y. Kim1, S. Hwang1, G. S. Hong1, E. Lee, H. Lee, C. Jeong, C. H. Kim, J. S. Yoo*, and D. H. Kim*, “Toward gasoline vehicles with zero harmful emissions by storing NO at Pd nanoparticle-CeO2 interface during the cold-start period”, Chem Catalysis, 2022, 2, 2289-2301.

[13] S. Hwang1, Y. Kim, J. Lee, E. Lee, H. Lee, C. Jeong, C. H. Kim, D. H. Kim*, “Promoting effect of CO on low-temperature NOx adsorption over Pd/CeO2 catalyst” Catalysis Today, 2022, 384-386, 88-96.

2021

[12] Y. Kim1, H. Lee, S. Yang, J. Lee, H. Kim, S. Hwang, S. W. Jeon, and D. H. Kim*, “Ultrafine Pd nanoparticles immobilized on amine-functionalized carbon nanotube for hydrogen production from formic acid”, Journal of Catalysis, 2021, 404, 324-333.

[11] J. Lee1, Y. Kim, S. Hwang. E. Lee, H. Lee, C. H. Kim, and D. H. Kim*, “Deactivation of Pd/Zeolites passive NOx adsorber induced by NO and H2O: Comparative study of Pd/ZSM-5 and Pd/SSZ-13” Catalysis Today, 2021, 360, 350-355.

[10] Y. Kim1, J. Sung1, S. Kang, J. Lee, M.-H. Kang, S. Hwang, H. Park, J. Kim, Y. Kim, E. Lee, G.-S. Park, D. H. Kim*, and J. Park*, “Uniform Synthesis of Palladium Species Confined in Small-pore Zeolite via Full Ion-exchange Investigated by Cryogenic Electron Microscopy”, Journal of Materials Chemistry A, 2021, 9, 19796-19806.

2020

[9] Y. Kim1, and D. H. Kim*, “Hydrogen production from formic acid dehydrogenation over a Pd supported on N-doped mesoporous carbon catalyst: A role of nitrogen dopant”, Applied Catalysis A: General, 2020, 608, 117887.

[8] J. Lee1, J. Kim, Y. Kim, S. Hwang, H. Lee, C. H. Kim, and D. H. Kim*, “Improving NOx storage and CO oxidation abilities of Pd/SSZ-13 by increasing its hydrophobicity” Applied Catalysis B: Environmental, 2020, 277, 119190.

[7] Y. Kim1, S.-h. Kim, H. C. Kim, and D. H. Kim* “Mechanistic insights on aqueous formic acid dehydrogenation over Pd/C catalyst for efficient hydrogen production”, Journal of Catalysis, 2020, 389, 506-516.

2019

[6] J. Kim1, Y. Kim1, M. H. Wiebenga, S. H. Oh, and D. H. Kim*, “Oxidation of C3H8, iso-C5H12 and C3H6 under near-stoichiometric and fuel-lean conditions over aged Pt-Pd/Al2O3 catalysts with different Pt:Pd ratios”, Applied Catalysis B: Environmental, 2019, 251, 283–294.

[5] Y. Kim1, S. Hwang1, J. Lee, Y. Ryou, H. Lee, C. H. Kim, and D. H. Kim*, “Comparison of NOx Adsorption/Desorption Behaviors over Pd/CeO2 and Pd/SSZ-13 as Passive NOx Adsorbers for Cold Start Application”, Emission Control Science and Technology, 2019, 5, 172–182.

[4] Y. Kim1, and D. H. Kim*, “Understanding the effect of Pd size on formic acid dehydrogenation via size-controlled Pd/C catalysts prepared by NaBH4 treatment”, Applied Catalysis B: Environmental, 2019, 244, 684-693.

[3] Y. Ryou1, J. Lee, Y. Kim, S. Hwang, H. Lee, C. H. Kim, and D. H. Kim*, “Effect of reduction treatments (H2 vs. CO) on the NO adsorption ability and the physicochemical properties of Pd/SSZ-13 passive NOx adsorber for cold start application”, Applied Catalysis A: General, 2019, 569, 28-34.

[2] J. Lee1, Y. Ryou, S. Hwang, Y. Kim, S.-J. Cho, H. Lee, C. H. Kim, and D. H. Kim*, “Comparative study of the mobility of Pd species in SSZ-13 and ZSM-5, and its implication for catalytic activity after hydro-thermal aging as Passive NOx Adsorbers (PNAs) for cold-start applications” Catalysis Science & Technology, 2019, 9, 163-173.

2018

[1] Y. Kim1, J. Kim, and D. H. Kim*, “Investigation on the enhanced catalytic activity of Ni-promoted Pd/C catalyst for formic acid dehydrogenation: Effects of preparation methods and Ni/Pd ratios” RSC Advances, 2018, 8, 2441-2448.