In-situ monitoring of atomically dispersed Pt sites supported on OMS-2 during CO2 activation

Scott Bamonte; Harshul S. Khanna; Inosh Perera; Meilin Li; Luisa F. Posada; Seth March; Nicholas A. Eddy; Ryuichi Shimogawa; Amelia Figueroa; Chao Li; Seth Shuster; Haiyan Tan; Nebojsa Marinkovic; Ashley R. Head; Dmitri N. Zakharov; Lu Ma; Pu Xian Gao; Anatoly I. Frenkel; Steven L. Suib

doi:10.1016/j.apcatb.2025.126016

In-situ monitoring of atomically dispersed Pt sites supported on OMS-2 during CO₂ activation

Scott Bamonte
, Harshul S. Khanna
, Inosh Perera
, Meilin Li
, Luisa F. Posada
, Seth March
, Nicholas A. Eddy
, Ryuichi Shimogawa
, Amelia Figueroa
, Chao Li
, Seth Shuster
, Haiyan Tan
, Nebojsa Marinkovic
, Ashley R. Head
, Dmitri N. Zakharov
, Lu Ma
, Pu Xian Gao
, Anatoly I. Frenkel
, Steven L. Suib

Materials Science and Engineering

Stony Brook University

University of Connecticut
Stony Brook University
Mitsubishi Chemical Holdings Corporation
Nova Southeastern University
Columbia University
Brookhaven National Laboratory

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

Abstract

Atomically dispersed catalysts have drawn great interest lately, as they showcase a high density of active sites, selectivity, and high turnover frequencies in oxidation chemistry due to labile oxygen activation. In contrast, the applications of these catalysts have lagged in reduction reactions due to the ambiguity caused by the sintering and restructuring of active sites. To bridge this gap, the evolution of Pt^{4 +} isomorphically substituted into an octahedral molecular sieve structure (OMS-2) under reductive conditions was correlatively characterized using multiple in-situ analytical techniques such as ambient pressure X-ray photoelectron spectroscopy, environmental transmission electron microscopy, and solid-state nuclear magnetic resonance. The surface dynamics of the Pt single atoms were revealed during the Reverse Water Gas Shift (RWGS) reaction, where the active sites were identified as two-coordinated platinum single atoms. Under reaction, we show nonbinding atoms adjacent to the single atoms restructured the motif of the single atoms to Pt²⁺ via ion mobility of potassium, increasing the activation energy by 25.6 kJ/mol. This work also highlights the potential for increased stability of the single atom sites via isomorphic substitution of the metal oxide support, since the Pt-OMS-2 catalyst retained activity for about 33 h before deactivation, after which nanoparticles were observed in TEM images.

Original language	English
Article number	126016
Journal	Applied Catalysis B: Environmental
Volume	383
DOIs	https://doi.org/10.1016/j.apcatb.2025.126016
State	Published - Apr 2026

Keywords

Atomically dispersed
CO2
Reverse water gas shift
XAS

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10.1016/j.apcatb.2025.126016

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Bamonte, S., Khanna, H. S., Perera, I., Li, M., Posada, L. F., March, S., Eddy, N. A., Shimogawa, R., Figueroa, A., Li, C., Shuster, S., Tan, H., Marinkovic, N., Head, A. R., Zakharov, D. N., Ma, L., Gao, P. X., Frenkel, A. I., & Suib, S. L. (2026). In-situ monitoring of atomically dispersed Pt sites supported on OMS-2 during CO₂ activation. Applied Catalysis B: Environmental, 383, Article 126016. https://doi.org/10.1016/j.apcatb.2025.126016

@article{c422c214508c459e8454e2e1fed906fc,

title = "In-situ monitoring of atomically dispersed Pt sites supported on OMS-2 during CO2 activation",

abstract = "Atomically dispersed catalysts have drawn great interest lately, as they showcase a high density of active sites, selectivity, and high turnover frequencies in oxidation chemistry due to labile oxygen activation. In contrast, the applications of these catalysts have lagged in reduction reactions due to the ambiguity caused by the sintering and restructuring of active sites. To bridge this gap, the evolution of Pt4 + isomorphically substituted into an octahedral molecular sieve structure (OMS-2) under reductive conditions was correlatively characterized using multiple in-situ analytical techniques such as ambient pressure X-ray photoelectron spectroscopy, environmental transmission electron microscopy, and solid-state nuclear magnetic resonance. The surface dynamics of the Pt single atoms were revealed during the Reverse Water Gas Shift (RWGS) reaction, where the active sites were identified as two-coordinated platinum single atoms. Under reaction, we show nonbinding atoms adjacent to the single atoms restructured the motif of the single atoms to Pt2+ via ion mobility of potassium, increasing the activation energy by 25.6 kJ/mol. This work also highlights the potential for increased stability of the single atom sites via isomorphic substitution of the metal oxide support, since the Pt-OMS-2 catalyst retained activity for about 33 h before deactivation, after which nanoparticles were observed in TEM images.",

keywords = "Atomically dispersed, CO2, Reverse water gas shift, XAS",

author = "Scott Bamonte and Khanna, \{Harshul S.\} and Inosh Perera and Meilin Li and Posada, \{Luisa F.\} and Seth March and Eddy, \{Nicholas A.\} and Ryuichi Shimogawa and Amelia Figueroa and Chao Li and Seth Shuster and Haiyan Tan and Nebojsa Marinkovic and Head, \{Ashley R.\} and Zakharov, \{Dmitri N.\} and Lu Ma and Gao, \{Pu Xian\} and Frenkel, \{Anatoly I.\} and Suib, \{Steven L.\}",

note = "Publisher Copyright: {\textcopyright} 2025 Elsevier B.V.",

year = "2026",

month = apr,

doi = "10.1016/j.apcatb.2025.126016",

language = "English",

volume = "383",

journal = "Applied Catalysis B: Environmental",

issn = "0926-3373",

publisher = "Elsevier B.V.",

}

Bamonte, S, Khanna, HS, Perera, I, Li, M, Posada, LF, March, S, Eddy, NA, Shimogawa, R, Figueroa, A, Li, C, Shuster, S, Tan, H, Marinkovic, N, Head, AR, Zakharov, DN, Ma, L, Gao, PX, Frenkel, AI & Suib, SL 2026, 'In-situ monitoring of atomically dispersed Pt sites supported on OMS-2 during CO₂ activation', Applied Catalysis B: Environmental, vol. 383, 126016. https://doi.org/10.1016/j.apcatb.2025.126016

TY - JOUR

T1 - In-situ monitoring of atomically dispersed Pt sites supported on OMS-2 during CO2 activation

AU - Bamonte, Scott

AU - Khanna, Harshul S.

AU - Perera, Inosh

AU - Li, Meilin

AU - Posada, Luisa F.

AU - March, Seth

AU - Eddy, Nicholas A.

AU - Shimogawa, Ryuichi

AU - Figueroa, Amelia

AU - Li, Chao

AU - Shuster, Seth

AU - Tan, Haiyan

AU - Marinkovic, Nebojsa

AU - Head, Ashley R.

AU - Zakharov, Dmitri N.

AU - Ma, Lu

AU - Gao, Pu Xian

AU - Frenkel, Anatoly I.

AU - Suib, Steven L.

PY - 2026/4

Y1 - 2026/4

N2 - Atomically dispersed catalysts have drawn great interest lately, as they showcase a high density of active sites, selectivity, and high turnover frequencies in oxidation chemistry due to labile oxygen activation. In contrast, the applications of these catalysts have lagged in reduction reactions due to the ambiguity caused by the sintering and restructuring of active sites. To bridge this gap, the evolution of Pt4 + isomorphically substituted into an octahedral molecular sieve structure (OMS-2) under reductive conditions was correlatively characterized using multiple in-situ analytical techniques such as ambient pressure X-ray photoelectron spectroscopy, environmental transmission electron microscopy, and solid-state nuclear magnetic resonance. The surface dynamics of the Pt single atoms were revealed during the Reverse Water Gas Shift (RWGS) reaction, where the active sites were identified as two-coordinated platinum single atoms. Under reaction, we show nonbinding atoms adjacent to the single atoms restructured the motif of the single atoms to Pt2+ via ion mobility of potassium, increasing the activation energy by 25.6 kJ/mol. This work also highlights the potential for increased stability of the single atom sites via isomorphic substitution of the metal oxide support, since the Pt-OMS-2 catalyst retained activity for about 33 h before deactivation, after which nanoparticles were observed in TEM images.

AB - Atomically dispersed catalysts have drawn great interest lately, as they showcase a high density of active sites, selectivity, and high turnover frequencies in oxidation chemistry due to labile oxygen activation. In contrast, the applications of these catalysts have lagged in reduction reactions due to the ambiguity caused by the sintering and restructuring of active sites. To bridge this gap, the evolution of Pt4 + isomorphically substituted into an octahedral molecular sieve structure (OMS-2) under reductive conditions was correlatively characterized using multiple in-situ analytical techniques such as ambient pressure X-ray photoelectron spectroscopy, environmental transmission electron microscopy, and solid-state nuclear magnetic resonance. The surface dynamics of the Pt single atoms were revealed during the Reverse Water Gas Shift (RWGS) reaction, where the active sites were identified as two-coordinated platinum single atoms. Under reaction, we show nonbinding atoms adjacent to the single atoms restructured the motif of the single atoms to Pt2+ via ion mobility of potassium, increasing the activation energy by 25.6 kJ/mol. This work also highlights the potential for increased stability of the single atom sites via isomorphic substitution of the metal oxide support, since the Pt-OMS-2 catalyst retained activity for about 33 h before deactivation, after which nanoparticles were observed in TEM images.

KW - Atomically dispersed

KW - CO2

KW - Reverse water gas shift

KW - XAS

UR - https://www.scopus.com/pages/publications/105020798721

U2 - 10.1016/j.apcatb.2025.126016

DO - 10.1016/j.apcatb.2025.126016

M3 - Article

SN - 0926-3373

VL - 383

JO - Applied Catalysis B: Environmental

JF - Applied Catalysis B: Environmental

M1 - 126016

ER -

In-situ monitoring of atomically dispersed Pt sites supported on OMS-2 during CO₂ activation

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Keywords

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