Laser Synthesis of Catalytically Active Materials for Organic Synthesis and Sensor Technology

S. Kochemirovskaia, M. Novomlinsky, Ilya Alyukov, Yulia Denisova, Diana Ischuk, Dmitriy Mokhorov, Vladimir Kochemirovsky
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Abstract

The catalytic activity of metallic nanomaterials depends on their surface morphology. A widely known method is the laser synthesis of metal nanostructures by depositing on dielectric surfaces from aqueous solutions containing metal complexes. The article analyzes the factors that favor the production of conductive, catalytic, and sensory-active deposits by laser method. It is shown that the two main factors is the presence of a large number of charged defects on heterophase surfaces and the structure of metal-containing complexes in solution. This is typical for mono- and bimetallic alloys, the components of which interact with the laser beams according to the autocatalytic type. Using the example of laser deposition from solutions of Co, Ni, Fe, Zn, and Ag salts with homo- and heterophase dielectrics, the sensory and catalytic properties of the deposits are compared by impedance spectroscopy and voltammetry. It has been shown that heterophase precipitation significantly enhances the catalysis response. It is known that the highest catalytic activity exhibits nanostructured and highly porous materials with a large specific surface area and materials containing surface heterogeneity in the form of charged acid-base centers. Such materials are necessary for the creation of new catalysts for organic synthesis and for the creation of new sensor materials for enzyme-free microbiosensors. Active development of new methods for the synthesis of such materials is underway. But not all of them give the expected result. Laser synthesis methods have the best prospects, including the method of laser-induced metal deposition. This is the laser synthesis of metal nanostructures by depositing dielectric surfaces from aqueous solutions containing metal complexes. Аrticle analyzes the factors that favor the production of conductive, catalytic, and sensory-active deposits by laser method. It is shown that the two main factors are the presence of a large number of charged defects on heterophase surfaces and the structure of a metal-contained complex in solution. This is typical for mono- and bimetallic alloys, the components of which interact with the laser beam according to the autocatalytic type. Using the example of laser deposition from solutions of Co, Ni, Fe, Zn, and Ag salts with homo- and heterophase dielectrics, the sensory and catalytic properties of the deposits are compared by impedance spectroscopy and voltammetry. It has been shown that heterophase precipitation significantly enhances the catalysis response. It is shown that the laser deposition reaction has an autocatalytic mechanism in a dynamic mode. The results of autocatalysis can be used in a stationary mode to create a microbiosensor for glucose, as well as to create a technology for laser refining rare metals and hydrogen energy in a dynamic mode.
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激光合成用于有机合成和传感器技术的催化活性材料
金属纳米材料的催化活性取决于其表面形态。一种广为人知的方法是从含有金属复合物的水溶液中通过激光在电介质表面沉积合成金属纳米结构。文章分析了有利于用激光方法生产导电、催化和感官活性沉积物的因素。研究表明,两个主要因素是异相表面存在大量带电缺陷和溶液中含金属复合物的结构。这是单金属和双金属合金的典型特征,其成分与激光束的相互作用属于自催化类型。以具有同相和异相电介质的钴、镍、铁、锌和银盐溶液的激光沉积为例,通过阻抗光谱法和伏安法比较了沉积物的感官和催化特性。众所周知,催化活性最高的是具有大比表面积的纳米结构和高孔隙材料,以及含有以带电酸碱中心为形式的表面异质性的材料。这种材料对于制造新的有机合成催化剂和制造新的无酶微生物传感器材料是必不可少的。目前正在积极开发合成此类材料的新方法。激光合成法前景最好,其中包括激光诱导金属沉积法。这是从含有金属复合物的水溶液中沉积电介质表面,用激光合成金属纳米结构的方法。文章分析了有利于用激光方法生产导电、催化和感官活性沉积物的因素。研究表明,两个主要因素是异相表面存在大量带电缺陷和溶液中含金属复合物的结构。这是单金属和双金属合金的典型特征,其中的成分根据自催化类型与激光束相互作用。以具有同相和异相电介质的 Co、Ni、Fe、Zn 和 Ag 盐溶液中的激光沉积为例,通过阻抗光谱法和伏安法比较了沉积物的感官和催化特性。研究表明,激光沉积反应具有动态模式下的自催化机制。自催化的结果可用于在固定模式下创建葡萄糖微生物传感器,以及在动态模式下创建激光提炼稀有金属和氢能的技术。
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