Darren W. Johnson

What is he best known for?

The fields of study he is best known for:

• Organic chemistry
• Hydrogen
• Catalysis

Darren W. Johnson spends much of his time researching Supramolecular chemistry, Crystallography, Nanotechnology, Ligand and Halide. His Supramolecular chemistry research incorporates elements of Self-assembly and Computational chemistry. His study explores the link between Crystallography and topics such as Metal ions in aqueous solution that cross with problems in Antiprism.

In his study, Main group element, Molecular recognition, Crystal engineering, Nanomaterials and Thin-film transistor is strongly linked to Group, which falls under the umbrella field of Nanotechnology. The concepts of his Ligand study are interwoven with issues in Metal and Rational design. His work deals with themes such as Ion, Proton NMR, Stereochemistry and Hydrogen bond, which intersect with Halide.

His most cited work include:

• Structural criteria for the design of anion receptors: the interaction of halides with electron-deficient arenes. (252 citations)
• Anion–π interaction augments halide binding in solution (153 citations)
• Solution Phase Measurement of Both Weak σ and C−H···X− Hydrogen Bonding Interactions in Synthetic Anion Receptors (141 citations)

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

Darren W. Johnson spends much of his time researching Supramolecular chemistry, Crystallography, Inorganic chemistry, Combinatorial chemistry and Nanotechnology. Supramolecular chemistry is the subject of his research, which falls under Molecule. His Crystallography study combines topics from a wide range of disciplines, such as Ligand, Nuclear magnetic resonance spectroscopy, Stereochemistry and Hydrogen bond.

As part of one scientific family, Darren W. Johnson deals mainly with the area of Hydrogen bond, narrowing it down to issues related to the Ion, and often Proton NMR. When carried out as part of a general Inorganic chemistry research project, his work on Hydroxide is frequently linked to work in Spectroscopy, therefore connecting diverse disciplines of study. He combines subjects such as Receptor, Oxide and Group with his study of Nanotechnology.

He most often published in these fields:

• Supramolecular chemistry (30.73%)
• Crystallography (23.44%)
• Inorganic chemistry (19.27%)

What were the highlights of his more recent work (between 2017-2021)?

• Combinatorial chemistry (16.67%)
• Supramolecular chemistry (30.73%)
• Hydrogen bond (11.46%)

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

Combinatorial chemistry, Supramolecular chemistry, Hydrogen bond, Disulfide bond and Dynamic covalent chemistry are his primary areas of study. Darren W. Johnson interconnects Functional group, Scaffold, Covalent bond, Molecule and Metal in the investigation of issues within Combinatorial chemistry. The study incorporates disciplines such as Molecular recognition, Anion binding and Amide in addition to Supramolecular chemistry.

His research integrates issues of Ion, Computational chemistry and Pyrene in his study of Hydrogen bond. His research in Disulfide bond intersects with topics in Polymer chemistry and Thioether. His work is dedicated to discovering how Dynamic covalent chemistry, Self-assembly are connected with Cyclophane and other disciplines.

Between 2017 and 2021, his most popular works were:

• The road to aryl CH⋯anion binding was paved with good intentions: fundamental studies, host design, and historical perspectives in CH hydrogen bonding (17 citations)
• Unique chemistries of metal-nitrate precursors to form metal-oxide thin films from solution: materials for electronic and energy applications (16 citations)
• Exploiting the Hydrogen Bond Donor/Acceptor Properties of PN‐Heterocycles: Selective Anion Receptors for Hydrogen Sulfate (9 citations)

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

• Organic chemistry
• Hydrogen
• Catalysis

Darren W. Johnson mostly deals with Combinatorial chemistry, Hydrogen bond, Anion binding, Supramolecular chemistry and Metal. The study of Combinatorial chemistry is intertwined with the study of Covalent bond in a number of ways. His work carried out in the field of Hydrogen bond brings together such families of science as Ion, Receptor, Aryl and Computational chemistry.

His Anion binding study combines topics in areas such as Anion receptor, Halide, Pyridinium, Halogen bond and Alkali metal. The Supramolecular chemistry study combines topics in areas such as Organic reaction, Catalysis, Ritter reaction and Amide. His Metal research is multidisciplinary, relying on both Maghemite, Oxide and Nanocrystal.

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