Marina V. Kirillova

What is she best known for?

The fields of study Marina V. Kirillova is best known for:

• Catalysis
• Organic chemistry
• Ion

As part of her research on Metal, studies on Coordination complex and Agostic interaction are part of the effort. Her Coordination complex study frequently links to related topics such as Metal. Her research brings together the fields of Methane and Organic chemistry. Marina V. Kirillova undertakes multidisciplinary studies into Catalysis and Carboxylation in her work. She connects Inorganic chemistry with Ion in her research. She performs integrative study on Ion and Vanadate. Vanadate and Vanadium are two areas of study in which she engages in interdisciplinary research. Her Vanadium study frequently involves adjacent topics like Inorganic chemistry. Marina V. Kirillova combines topics linked to Carboxylic acid with her work on Polymer chemistry.

Her most cited work include:

• Multinuclear Copper Triethanolamine Complexes as Selective Catalysts for the Peroxidative Oxidation of Alkanes under Mild Conditions (240 citations)
• Multicopper complexes and coordination polymers for mild oxidative functionalization of alkanes (181 citations)
• Mild Peroxidative Oxidation of Cyclohexane Catalyzed by Mono-, Di-, Tri-, Tetra- and Polynuclear Copper Triethanolamine Complexes (158 citations)

What are the main themes of her work throughout her whole career to date

While working on this project, Marina V. Kirillova studies both Organic chemistry and Physical chemistry. She performs multidisciplinary study on Physical chemistry and Organic chemistry in her works. Marina V. Kirillova connects Catalysis with Hydrogen peroxide in her research. While working on this project, Marina V. Kirillova studies both Inorganic chemistry and Medicinal chemistry. In her works, Marina V. Kirillova undertakes multidisciplinary study on Medicinal chemistry and Inorganic chemistry. She performs integrative study on Polymer chemistry and Polymer. Marina V. Kirillova brings together Polymer and Polymer chemistry to produce work in her papers. She merges Biochemistry with Receptor in her research. Marina V. Kirillova integrates many fields, such as Receptor and Ligand (biochemistry), in her works.

Marina V. Kirillova most often published in these fields:

• Organic chemistry (100.00%)
• Catalysis (81.94%)
• Inorganic chemistry (34.72%)

What were the highlights of her more recent work (between 2019-2022)?

• Organic chemistry (100.00%)
• Catalysis (66.67%)
• Polymer (55.56%)

In recent works Marina V. Kirillova was focusing on the following fields of study:

There are a combination of areas like Action (physics) and Computational chemistry integrated together with her Quantum mechanics study. Marina V. Kirillova performs integrative Computational chemistry and Quantum mechanics research in her work. She merges many fields, such as Organic chemistry and Combinatorial chemistry, in her writings. She incorporates Combinatorial chemistry and Organic chemistry in her studies. In her works, Marina V. Kirillova undertakes multidisciplinary study on Catalysis and Knoevenagel condensation. Marina V. Kirillova merges Polymer with Silsesquioxane in her study. Polymer chemistry and Polymer are two areas of study in which she engages in interdisciplinary work. Chemical engineering is closely attributed to Hydrothermal synthesis in her study. As part of her studies on Hydrothermal synthesis, Marina V. Kirillova often connects relevant areas like Chemical engineering.

Between 2019 and 2022, her most popular works were:

• H-Bonded and metal(ii)–organic architectures assembled from an unexplored aromatic tricarboxylic acid: structural variety and functional properties (17 citations)
• Introducing a flexible tetracarboxylic acid linker into functional coordination polymers: synthesis, structural traits, and photocatalytic dye degradation (12 citations)
• Coordination polymers from an unexplored biphenyl-tricarboxylate linker: hydrothermal synthesis, structural traits and catalytic cyanosilylation (11 citations)

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