Linda J. W. Shimon

What is she best known for?

The fields of study she is best known for:

• Organic chemistry
• Catalysis
• Enzyme

Her primary areas of study are Medicinal chemistry, Stereochemistry, Ligand, Catalysis and Pincer movement. Her Medicinal chemistry research is multidisciplinary, relying on both Hydride, Nickel, Cyclooctene, Photochemistry and Deprotonation. Her study in Stereochemistry is interdisciplinary in nature, drawing from both Crystal growth, Triple bond, Crystal structure, Dissolution and Molecule.

Her research integrates issues of Pyridine, Rhodium, Aromatization, Reactivity and Metal in her study of Ligand. Her research in Catalysis intersects with topics in Inorganic chemistry and Hydrogen. In her study, Nitrile and Benzonitrile is inextricably linked to Methylene, which falls within the broad field of Pincer movement.

Her most cited work include:

• Efficient hydrogenation of organic carbonates, carbamates and formates indicates alternative routes to methanol based on CO2 and CO (409 citations)
• Low‐Pressure Hydrogenation of Carbon Dioxide Catalyzed by an Iron Pincer Complex Exhibiting Noble Metal Activity (370 citations)
• Consecutive thermal H2 and light-induced O2 evolution from water promoted by a metal complex. (368 citations)

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

Her scientific interests lie mostly in Stereochemistry, Medicinal chemistry, Crystallography, Ligand and Photochemistry. Her Stereochemistry research incorporates themes from Pyridine, Iridium and Phosphine. In her study, Polymer chemistry is strongly linked to Reactivity, which falls under the umbrella field of Medicinal chemistry.

Her Crystallography study incorporates themes from Inorganic chemistry, Crystallization and Molecule. Her research in Ligand is mostly concerned with Pincer movement. Her studies in Photochemistry integrate themes in fields like Oxidative addition and Platinum.

She most often published in these fields:

• Stereochemistry (24.16%)
• Medicinal chemistry (23.85%)
• Crystallography (22.02%)

What were the highlights of her more recent work (between 2015-2021)?

• Catalysis (13.76%)
• Crystallography (22.02%)
• Nanotechnology (6.12%)

In recent papers she was focusing on the following fields of study:

Her primary areas of investigation include Catalysis, Crystallography, Nanotechnology, Supramolecular chemistry and Metal. Her Catalysis study integrates concerns from other disciplines, such as Manganese, Medicinal chemistry and Polymer chemistry. The study incorporates disciplines such as Selectivity, Aryl, Corrole and Trimethylsilylacetylene in addition to Medicinal chemistry.

Her Crystal structure study in the realm of Crystallography interacts with subjects such as Amphiphile. Her research investigates the link between Nanotechnology and topics such as Peptide that cross with problems in Biophysics and Combinatorial chemistry. Her Pincer movement research is within the category of Ligand.

Between 2015 and 2021, her most popular works were:

• Manganese-Catalyzed Environmentally Benign Dehydrogenative Coupling of Alcohols and Amines to Form Aldimines and H2: A Catalytic and Mechanistic Study. (207 citations)
• Self-assembling dipeptide antibacterial nanostructures with membrane disrupting activity. (120 citations)
• Manganese-Catalyzed Hydrogenation of Esters to Alcohols. (102 citations)

In her most recent research, the most cited papers focused on:

• Organic chemistry
• Catalysis
• Enzyme

Linda J. W. Shimon mostly deals with Catalysis, Nanotechnology, Supramolecular chemistry, Organic chemistry and Diphenylalanine. Her Catalysis study combines topics from a wide range of disciplines, such as Combinatorial chemistry, Stereochemistry and Base. Her work in the fields of Nanotechnology, such as Self-assembly and Nanostructure, overlaps with other areas such as Fabrication.

Electronics, Thermal stability, Semiconductor and Surface modification is closely connected to Photoluminescence in her research, which is encompassed under the umbrella topic of Supramolecular chemistry. Her work in Ruthenium covers topics such as Hydride which are related to areas like Ligand. Her Trimethylsilylacetylene study deals with Homogeneous catalysis intersecting with Medicinal chemistry.

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