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Editorial

Nanoparticles in Catalysis

by
Alexander D. Modestov
* and
Vitali A. Grinberg
Frumkin Institute of Physical Chemistry and Electrochemistry, Russian Academy of Sciences, Leninsky Prospekt 31, Building 4, 119071 Moscow, Russia
*
Author to whom correspondence should be addressed.
Catalysts 2024, 14(7), 418; https://doi.org/10.3390/catal14070418
Submission received: 26 June 2024 / Accepted: 28 June 2024 / Published: 29 June 2024
(This article belongs to the Special Issue Nanoparticles in the Catalysis)
Nanoparticles (NPs) are defined as objects with dimensions ranging from 10−9 to 10−7 m [1]. Objects smaller than 2 nm are usually called clusters. NPs have been around for thousands of years, although they were not always recognized as NPs. One of the most famous ancient artifacts is the Lycurgus Cup, held in the British Museum. Its fascinating color is due to the fact that gold and silver NPs are embedded in the glasswork. Currently NPs find practical applications in a broad variety of areas, including in medicine, cosmetics, catalysis, photocatalysis, environmental protection and remediation, optics, electronics, and construction materials such as concrete, coatings, and paints. Because of their nanometer size, a substantial number of the atoms or molecules constituting these particles reside on the particle surface and interact with environment. Surface layer properties influence nanosized materials’ size-dependent physical and chemical properties. The stability, solubility, and chemical and biological activity of NPs can be modified by the functionalization of the particles, which involves attaching something to their surfaces’ molecules or functional groups. NPs of particular shapes, including spherical NPs, nanorods, nanosheets, nanocubes, and nanocages, exhibit shape-dependent properties. NPs containing two or more phases, like metals attached to oxides, or heterojunctions of two semiconductor NPs acquire properties which each phase, in their clear state, do not possess. The catalytic activity of metal NPs can be enhanced dramatically by ensuring attachment to a proper carrier. The high surface-to-volume ratios of NPs enable the preservation of expensive catalytic materials such as noble metals in catalyst manufacturing, thus promoting the wide spread of important technologies. The catalytic converters of modern cars with internal combustion engines reduce hydrocarbon emissions, as well as the emission of nitrous oxide and carbon monoxide. The so-called three-way catalysts of converters contain NPs based on Pt, Pd, Rh, and other metals on oxide supports. More than half of the Pd produced globally, as well as nearly half of the Pt produced globally, is used in catalytic converters.
As far as we know, the first scientific article related to catalysis by characterized NPs was published in 1941 by Rampino and Nord [2]. The authors used Pd and Pt NPs stabilized by polyvinyl alcohol to catalyze the hydrogenation of castor and fish oils at room temperature in water and water–alcohol mixtures. However, the surge in research on heterogeneous catalysis by NPs happened later, after the work of Haruta and co-workers was published [3,4]. This research group oxidized CO to CO2 using O2 at temperatures as low as −70 °C and a catalyst composed of 5 nm gold NPs coated with either Fe, Ni, or Co oxides. Currently, searching Google using the terms “catalysis” and “nanoparticles” returns more than 2 million records.
The works published in this Special Issue address most of the fields of application for NPs in catalysis. This Special Issue contains 11 articles, with some being research articles and others being review articles.
The emission of volatile organic compounds (VOCs) by industries causes many health problems, such as sensory stimulation, allergies, and chronic respiratory diseases. The catalytic oxidation of toluene, as a model VOC, was studied using a synthesized Pt/CeO2-NS composite catalyst in contribution 1. Pt NPs were attached to synthesized 50–200 nm ceria nanospheres by the reduction of chloroplatinic acid in the presence of L-asparagine. In toluene oxidation, the synthesized Pt/CeO2-NS catalysts were superior to Pt/CeO2 catalysts synthesized using commercial ceria. The effect of L-asparagine is ascribed to the inhibition of cerium formate formation and coordination with Pt.
The use of hydrogen as an energy carrier requires the development of efficient technologies for hydrogen production, transportation, and storage and the transformation of its chemical energy to electric power. Fuel cells with proton-conducting membranes (PEM FCs) are instruments that can be used for the efficient transformation of hydrogen’s chemical energy into electricity. The propagation of hydrogen-based energy technologies, to a large extent, depends on the efficiency and stability of Pt-based electrocatalysts, which are used in the gas diffusion electrodes of fuel cells. The relatively low stability of carbon black supports of oxygen reduction catalysts can cause fuel cells to degrade. The authors of contribution 2 propose a way to increase the stability of electrocatalysts based on carbon-supported Pt. The authors synthesized a durable Pt-based electrocatalyst via depositing Pt NPs on the surfaces of carbon nanofibers. Chemically stable carbon nanofibers that could be used in high-temperature PEM FCs operational at 160–190 °C were prepared by electrospinning a polyacrylonitrile solution, followed by pyrolysis.
The use of bimetallic and multi-component NP catalysts in PEM FCs improves the activity and durability of Pt-based electrocatalysts. The authors of contribution 3 synthesized bimetallic PtM/C (M = Co, Ni, Cu, Ru) by the wet synthesis route. Special attention was paid to the adoptability of the method for electrocatalyst batch production. The activity of a PtCu/C oxygen reduction catalyst was found to be superior to that of other synthesized materials.
Chemical methods for synthesizing multi-component metal NPs usually employ toxic reagents. Green synthesis using biological reactants such as bacteria, plants, fungi, algae, waste biomass is one of the most promising methods that can be used to avoid environmental pollution and prevent the need for environment protection measures. Contribution 4 provides a perspective on the synthesis of trimetallic NPs using biological agents. The limitations of the synthesis method; the applications of and prospects for the trimetallic NPs in different areas of research, such as anticancer research; and their antimicrobial activity, drug delivery, and catalytic activity are discussed.
The emission of carbon dioxide due to fossil fuel burning is the main cause of ongoing climate change. The reduction of CO2 to useful compounds, such as methane or methanol, is an innovative way to keep CO2 concentrations in the atmosphere at a reasonable level. The authors of contribution 5 address issues related to the reduction of CO2 to useful products using mono- and bimetallic nanocatalysts and other metal/metal oxide catalysts supported on biochar. Biochar, produced by the thermochemical treatment of biomass, is especially useful as a porous support for catalysts prepared by thermochemical methods. The catalytic reduction of gaseous CO2 to methanol by the use of metal NP catalysts supported on biochar can be carried out at relatively low temperatures, specifically in the 200–500 °C range.
The authors of the contribution 6 explored the possibility of converting waste from he brewing industry, i.e., brewer’s spent grain, into biochar supports for Ag-Cu NP catalysts. In this study, oxidation by hydrogen peroxide in aqueous solutions of model pollutant compounds, namely Methyl Orange and Methylene Blue, in the presence of suspended catalysts was monitored by UV-vis spectroscopy.
Another way to capture CO2 is to photochemically reduce it to methanol. The authors of contribution 7 reduced CO2 to methanol in an irradiated aqueous solution. Visible light was absorbed by nanoparticles of a 15% Bi2O3/CeO2 photocatalyst suspended in solution. Photoexcited electron–hole pairs were separated by Bi2O3/CeO2 heterojunction. The reduction of CO2 occurred at Bi2O3, while water oxidation with the release of oxygen occurred at ceria.
The biodiesel manufacturing industry produces high amounts of glycerol, which is not needed in such large quantities. Glycerol can be converted to useful products such as acrylic acid and lactic acid by mild oxidation. Oxidizing the carbon dioxide of organic pollutants dissolved in water is a method for industrial waste water treatment. Photoassisted electrochemical oxidation of methanol, ethylene glycol, glycerol, and 5,6,7,8-tetrahydro-2-naphthol was carried out in contribution 8. Organic matter oxidation was conducted on thin-film hematite photoanodes irradiated with visible light. The hematite film of the photoanodes was modified by titania.
Diesel-powered light- and heavy-duty vehicles, as well as agricultural and construction machinery, emit particulate matter, with soot making up the vast majority. Diesel particulate filters capture more than 85% of the soot in the exhaust. The soot accumulated in the filter can be removed by periodic burning using appropriate catalysts embedded in the filter. In contribution 9, CeO2 and Co3O4 NP catalysts were synthesized by precipitation from solution, followed by calcination at 600 °C. Precipitation was performed by introducing microdroplets of Ce(NO3)3 or Co(NO3)2 into alkaline aqueous solutions. Oxide NPs were anchored to stainless steel or ceramic supports by colloidal cerium oxide. The catalytic activity of the synthesized materials in soot oxidation was evaluated. For this evaluation, samples containing carbon particles, which were collected from the filter of a real diesel engine, were mixed with synthesized catalyst particles and subjected to temperature-programmed oxidation.
In the context of fuels, replacing raw fossil materials with renewable materials is a way to stabilize the levels of carbon dioxide in the atmosphere. Renewable sources of hydrocarbons include products of biomass fermentation and lignin, which is a complex three-dimensional crystalline polymer contained in plant cells and some algae. Every year, 150–200 million tons of lignin waste are generated. In contribution 10, a microwave-assisted plasma catalytic process was used to convert lignin and fuel oil into hydrogen, synthesis gas, and liquid hydrocarbons in the presence of nano-sized cobalt-containing systems. The authors found that it is probable that the role of Co-containing particles in catalytic processes consists in activating the carbon bonds of lignin, which substantially increases the microwave absorption capacity of the system as a whole. The process was conducted in a CO2 atmosphere. In the presence of cobalt-containing particles, the temperature of the reaction zone during microwave treatment reached 800 °C.
The contamination of water resources, including sea water, by salts of heavy metals can cause multiple effects that are damaging to human health. Even some sea fish contain dangerous levels of mercury ions. The maximum contaminant level for inorganic mercury in drinking water is only 2 ppb. Measuring mercury concentrations in water from many sources at so low levels requires highly sensitive, selective, and cost-effective instruments. The authors of contribution 11 devised an electrochemical sensor tailored for the detection of Hg2+ in water at a lower detection limit of 0.18 ppb Hg2+. Using the instrument, the detection of Hg2+ is unaffected by other ions commonly found in environmental fluids. The voltametric sensor of the instrument is a glassy carbon electrode with attached silver NPs. The silver NPs were synthesized by the reduction of silver nitrate in the presence of xanthan gum. This instrument acts as a reducing and capping agent.
The Guest Editors greatly appreciate the scientific novelty of the articles which comprise this Special Issue. It is important to mention that all the articles in the Special Issue are focused on environmental protection. The number of environmental problems that the world is facing is only increasing. Thus, the need to develop safe, efficient, and cheap catalysts will only become more urgent.

Author Contributions

Both authors contributed to this editorial equally. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Acknowledgments

We would like to thank the Editorial Board of Catalysts for giving us the opportunity to lead this Special Issue as Guest Editors. Special thanks are due to the reviewers for dedicating their time and effort to reviewing. We are especially thankful to all the authors for submitting the high-quality research and review papers that comprise this Special Issue.

Conflicts of Interest

The authors declare no conflicts of interest.

List of Contributions

  • Hao, Y.; Chen, S.; Zhang, X.; Chen, T. L-asparagine Assisted Synthesis of Pt/CeO2 Nanospheres for Toluene Combustion. Catalysts 2022, 12, 887.
  • Ponomarev, I.; Skupov, K.; Zhigalina, O.; Khmelenin, D.; Ponomarev, I.; Vtyurina, E.; Cherkovskiy, E.; Basu, V.; Modestov, A. Deposition of Pt Nanoparticles by Ascorbic Acid on Composite Electrospun Polyacrylonitrile-Based Carbon Nanofiber for HT-PEM Fuel Cell Cathodes. Catalysts 2022, 12, 891.
  • Belenov, S.; Pavlets, A.; Paperzh, K.; Mauer, D.; Menshikov, V.; Alekseenko, A.; Pankov, I.; Tolstunov, M.; Guterman, V. The PtM/C (M = Co, Ni, Cu, Ru) Electrocatalysts: Their Synthesis, Structure, Activity in the Oxygen Reduction and Methanol Oxidation Reactions, and Durability. Catalysts 2023, 13, 243.
  • Roy, A.; Kunwar, S.; Bhusal, U.; Alghamdi, S.; Almehmadi, M.; Alhuthali, H.; Allahyani, M.; Hossain, M.; Hasan, M.; Sarker, M.; Azlina, M. Bio-Fabrication of Trimetallic Nanoparticles and Their Applications. Catalysts 2023, 13, 321.
  • Tang, M.; Gamal, A.; Bhakta, A.; Jlassi, K.; Abdullah, A.; Chehimi, M. Carbon Dioxide Methanation Enabled by Biochar-Nanocatalyst Composite Materials: A Mini-Review. Catalysts 2024, 14, 155.
  • Boubkr, L.; Bhakta, A.; Snoussi, Y.; Moreira Da Silva, C.; Michely, L.; Jouini, M.; Ammar, S.; Chehimi, M. Highly Active Ag-Cu Nanocrystal Catalyst-Coated Brewer’s Spent Grain Biochar for the Mineralization of Methyl Orange and Methylene Blue Dye Mixture. Catalysts 2022, 12, 1475.
  • Mostafa, M.; Shawky, A.; Zaman, S.; Narasimharao, K.; Abdel Salam, M.; Alshehri, A.; Khdary, N.; Al-Faifi, S.; Chowdhury, A. Visible-Light-Driven CO2 Reduction into Methanol Utilizing Sol-Gel-Prepared CeO2-Coupled Bi2O3 Nanocomposite Heterojunctions. Catalysts 2022, 12, 1479.
  • Grinberg, V.; Emets, V.; Mayorova, N.; Averin, A.; Shiryaev, A. Photoelectrocatalytic Properties of a Ti-Modified Nanocrystalline Hematite Film Photoanode. Catalysts 2022, 12, 1243.
  • Godoy, M.; Banús, E.; Bon, M.; Miró, E.; Milt, V. Synthesis of Co, Ce Oxide Nanoparticles Using an Aerosol Method and Their Deposition on Different Structured Substrates for Catalytic Removal of Diesel Particulate Matter. Catalysts 2023, 13, 660.
  • Tsodikov, M.; Bukhtenko, O.; Naumkin, A.; Nikolaev, S.; Chistyakov, A.; Konstantinov, G. Activity and Structure of Nano-Sized Cobalt-Containing Systems for the Conversion of Lignin and Fuel Oil to Synthesis Gas and Hydrocarbons in a Microwave-Assisted Plasma Catalytic Process. Catalysts 2022, 12, 1315.
  • Shakeel, S.; Talpur, F.; Sirajuddin; Anwar, N.; Iqbal, M.; Ibrahim, A.; Afridi, H.; Unar, A.; Khalid, A.; Ahmed, I.; Lai, W.; Bashir, M. Xanthan Gum-Mediated Silver Nanoparticles for Ultrasensitive Electrochemical Detection of Hg2+ Ions from Water. Catalysts 2023, 13, 208.

References

  1. Vert, M.; Doi, Y.; Hellwich, K.-H.; Hess, M.; Hodge, P.; Kubisa, P.; Rinaudo, M.; Schué, F. Terminology for biorelated polymers and applications (IUPAC Recommendations 2012). Pure Appl. Chem. 2012, 84, 377–410. [Google Scholar] [CrossRef]
  2. Rampino, L.D.; Nord, F.F. Preparation of Palladium and Platinum Synthetic High Polymer Catalysts and the Relationship between Particle Size and Rate of Hydrogenation. J. Am. Chem. Soc. 1941, 63, 2745–2749. [Google Scholar] [CrossRef]
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Modestov, A.D.; Grinberg, V.A. Nanoparticles in Catalysis. Catalysts 2024, 14, 418. https://doi.org/10.3390/catal14070418

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Modestov AD, Grinberg VA. Nanoparticles in Catalysis. Catalysts. 2024; 14(7):418. https://doi.org/10.3390/catal14070418

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Modestov, Alexander D., and Vitali A. Grinberg. 2024. "Nanoparticles in Catalysis" Catalysts 14, no. 7: 418. https://doi.org/10.3390/catal14070418

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Modestov, A. D., & Grinberg, V. A. (2024). Nanoparticles in Catalysis. Catalysts, 14(7), 418. https://doi.org/10.3390/catal14070418

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