In the relentless pursuit of efficient and sustainable catalytic systems, the stabilization of atom-precise noble metal clusters presents a tantalizing frontier. These clusters, distinguished by their remarkable atom economy and unique size-dependent properties, hold tremendous promise for industrial catalytic applications ranging from fine chemical synthesis to energy conversion processes. However, a perennial challenge has been their intrinsic tendency to agglomerate under reaction conditions, which compromises their stability and catalytic performance. Now, a groundbreaking study has unveiled a novel strategy to stabilize low-nuclearity platinum nanoclusters by confining them within nanoscale oxide islands, marking a significant stride toward practical implementation of these ultrafine catalysts.
The research, conducted by Chen et al., focuses on platinum clusters composed of between seven and fourteen atoms, manifesting as ultrasmall entities approximately 0.7 nanometers in diameter. The clusters were synthesized through a controlled approach involving the reduction of isolated platinum single atoms anchored on cerium oxide (CeOₓ) nanoislands, itself supported on a porous silica substrate. This intricate architecture serves as a spatially confined microenvironment, effectively preventing the migration and coalescence of platinum atoms into larger, less active aggregates. The methodology leverages the unique interplay between the platinum species and the ceria support to maintain cluster integrity during high-temperature treatments.
An essential aspect of the synthesis involves reductive treatments in a hydrogen atmosphere at elevated temperatures—specifically, 400 degrees Celsius—facilitating controlled nucleation and growth of clusters from the dispersed single atoms. Remarkably, the study reveals that subsequent redox cycling at similar or higher temperatures induces a dynamic process of cluster formation and fragmentation. Even so, platinum remains spatially tethered within the ceria nanoislands, underscoring the robustness of the confinement strategy. This confinement is critical as it yields exceptional thermal and chemical stability, enabling the clusters to resist sintering—a common pathway to loss of catalytic surface area—at temperatures reaching 600 degrees Celsius under atmospheric pressure.
Beyond stability, the catalytic prowess of these atom-precise platinum clusters was evaluated in the context of ethylene hydrogenation, an industrially relevant reaction for producing ethane and a benchmark test for hydrogenation catalysts. Strikingly, the clusters exhibited higher catalytic activity than their mononuclear platinum counterparts, suggesting a non-linear relationship between cluster size and reactivity. Furthermore, they outperformed both smaller and larger platinum aggregates, highlighting that an optimal cluster size exists where catalytic efficiency is maximized. These findings were corroborated by computational modeling, which elucidated the electronic and geometric factors underpinning the observed behavior.
The confinement strategy not only preserves the nuclearity of platinum clusters but also stabilizes them within a structurally and chemically tailored nanoscale environment. Cerium oxide, with its well-known oxygen storage capacity and redox flexibility, plays a dual role: it acts as a physical host limiting cluster migration while also participating in electron transfer processes that modulate platinum’s chemical state and reactivity. This synergy between metal cluster and oxide support opens avenues for fine-tuning catalytic properties via precise control over cluster-support interactions.
One of the most compelling implications of this work is its potential scalability for industrial catalysis. Traditionally, atomically dispersed catalysts or ultrasmall clusters have struggled with longevity under reaction conditions involving elevated temperatures and reactive atmospheres. The presented confinement method, demonstrably effective at temperatures up to 600 degrees Celsius, suggests a robust platform adaptable to various catalytic systems. Porous silica, a widely available and tunable support, provides the structural backbone, while the ceria nanoislands define spatially confined domains for metal-host interaction.
The research also advances fundamental understanding of cluster dynamics under operational conditions. Through redox cycling experiments paired with spectroscopic and microscopic analyses, the team tracked the reversible assembly and disassembly of platinum clusters. This insight underscores that, rather than static entities, these clusters can exhibit dynamic behavior while maintaining overall stability within constrained environments. Such knowledge is vital for designing catalysts capable of withstanding the rigor of industrial processing without performance degradation.
Crucially, this approach addresses major challenges in catalyst design—namely, balancing activity, selectivity, and durability at the nanoscale. By preserving atom-precision, the clusters maintain high specific activity due to maximal atom utilization, while the tailored support environment enhances stability and modulates electronic properties. This triad of benefits positions these platinum nanoclusters as model systems to explore catalytic phenomena that depend intimately on cluster nuclearity.
The interplay of synthesis, characterization, catalytic testing, and computational modeling presented in this work exemplifies a comprehensive strategy to harness atom-precise catalysts. Density functional theory calculations provided mechanistic insights into reaction pathways and energy landscapes, explaining how cluster size influences adsorbate binding and activation energies. These theoretical results aligned seamlessly with observed catalytic trends, reinforcing confidence in the design principles proposed.
Looking forward, this study paves the way for exploration of other noble metal clusters, potentially extending beyond platinum to palladium, rhodium, or gold systems with tailored supports. The concept of nanoscale confinement via oxide nanoislands could be generalized, offering a versatile toolkit for stabilizing ultrafine catalysts in diverse chemical reactions. Moreover, integrating such systems into continuous flow reactors or integrating with membrane technologies may yield practical catalytic modules for green chemical manufacturing.
The exceptional thermal stability coupled with enhanced catalytic activity observed here challenges long-held assumptions about the trade-offs between small cluster size and robustness. By enabling precise nuclearity control alongside sinter-resistance, this work represents a paradigm shift that could influence catalyst design across multiple sectors, from petrochemicals to environmental remediation and renewable energy technologies.
In sum, the innovative confinement of atomically precise platinum clusters within ceria nanoislands supported on porous silica not only surmounts the notorious issue of sintering but also unveils a striking size-dependent catalytic performance profile. This confluence of stability and reactivity heralds a new era in the rational design of heterogeneous catalysts at the atomic scale. As chemical industries increasingly prioritize efficiency and sustainability, such advances in catalyst architecture are poised to play a transformative role.
The revelation that cluster nuclearity—maintained under harsh redox and thermal conditions—can be harnessed to optimize catalytic function adds a fundamental descriptor to catalyst design parameters. Atomic precision, long sought after but elusive in practical systems, is thus rendered achievable and functional. This sets a precedent for future studies focusing on precise atomic arrangement as a lever to tune catalytic landscapes with unprecedented control.
Ultimately, the collaborative efforts encompassing synthetic chemistry, materials science, surface characterization, reaction engineering, and theoretical modeling showcased in this research epitomize the multidisciplinary approach required to unlock the full potential of nanocatalysts. By bridging these domains, the study illuminates pathways to not only understand but also manipulate catalytic phenomena at the very limits of matter.
Subject of Research:
Stabilization and catalytic activity of atom-precise low-nuclearity platinum nanoclusters confined on cerium oxide nanoislands supported on porous silica.
Article Title:
Stabilizing supported atom-precise low-nuclearity platinum cluster catalysts by nanoscale confinement.
Article References:
Chen, Y., Zhao, J., Zhao, X. et al. Stabilizing supported atom-precise low-nuclearity platinum cluster catalysts by nanoscale confinement. Nat Chem Eng 2, 38–49 (2025). https://doi.org/10.1038/s44286-024-00162-x
Image Credits: AI Generated
DOI: https://doi.org/10.1038/s44286-024-00162-x
Tags: agglomeration challenges in catalystsatom economy in nanomaterialsatom-precise noble metal synthesiscatalytic applications of ultrafine catalystscerium oxide support for catalystsenergy conversion processes using nanoclustersfine chemical synthesis with platinumhigh-temperature stability of metal clustersnanoscale confinement of platinum clustersporous silica substrate in catalysisspatial confinement in catalytic systemsstability of platinum nanoclusters
