What is he best known for?
The fields of study he is best known for:
- Catalysis
- Organic chemistry
- Hydrogen
Hideshi Hattori mostly deals with Catalysis, Inorganic chemistry, Adsorption, Hydrogen and Organic chemistry.
His Catalysis research incorporates themes from Photochemistry and Nitromethane.
His Inorganic chemistry study integrates concerns from other disciplines, such as Pyridine, Oxide, Methanol, Platinum and Metal.
His research integrates issues of Pentane, Infrared spectroscopy, Lewis acids and bases, Cyclohexane and Methylcyclopentane in his study of Pyridine.
Specifically, his work in Adsorption is concerned with the study of Desorption.
His Isomerization research focuses on Oxidizing agent and how it connects with Diphenylamine, Triethylamine, 1-Butene and Triphenylamine.
His most cited work include:
- The acidic properties of TiO2-SiO2 and its catalytic activities for the amination of phenol, the hydration of ethylene and the isomerization of butene (212 citations)
- Surface properties of zirconium oxide and its catalytic activity for isomerization of 1-butene (157 citations)
- Nucleosides and Nucleotides. 158. 1-(3-C-Ethynyl-β-d-ribo-pentofuranosyl)- cytosine, 1-(3-C-Ethynyl-β-d-ribo-pentofuranosyl)uracil, and Their Nucleobase Analogues as New Potential Multifunctional Antitumor Nucleosides with a Broad Spectrum of Activity1 (110 citations)
What are the main themes of his work throughout his whole career to date?
His primary areas of study are Catalysis, Inorganic chemistry, Isomerization, Hydrogen and Organic chemistry.
Selectivity is the focus of his Catalysis research.
His research in Inorganic chemistry intersects with topics in Oxide, Platinum, Desorption, Adsorption and Magnesium.
His biological study spans a wide range of topics, including Zeolite and Infrared spectroscopy.
The various areas that Hideshi Hattori examines in his Isomerization study include 1-Butene, Ammonia, Butene, Cyclopropane and Double bond.
His study in Hydrogen is interdisciplinary in nature, drawing from both Surface diffusion and Heterogeneous catalysis.
He most often published in these fields:
- Catalysis (75.20%)
- Inorganic chemistry (58.66%)
- Isomerization (27.56%)
What were the highlights of his more recent work (between 1998-2018)?
- Catalysis (75.20%)
- Inorganic chemistry (58.66%)
- Hydrogen (20.08%)
In recent papers he was focusing on the following fields of study:
His scientific interests lie mostly in Catalysis, Inorganic chemistry, Hydrogen, Organic chemistry and Adsorption.
His study on Catalysis is mostly dedicated to connecting different topics, such as Photochemistry.
His studies deal with areas such as Oxide, Reactivity, Oxygen, Selectivity and Acetic acid as well as Inorganic chemistry.
Hideshi Hattori combines subjects such as Surface diffusion, Pyridine, Hydrodesulfurization and Platinum with his study of Hydrogen.
Hideshi Hattori interconnects Binary compound, Dissociation and Infrared spectroscopy in the investigation of issues within Adsorption.
In his research, Ammonia is intimately related to Cyclohexane, which falls under the overarching field of Isomerization.
Between 1998 and 2018, his most popular works were:
- Alcoholysis of ester and epoxide catalyzed by solid bases (72 citations)
- IR study of acid sites on WO3–ZrO2 and Pt/WO3–ZrO2 (67 citations)
- Nitroaldol reaction over solid base catalysts (57 citations)
In his most recent research, the most cited papers focused on:
- Catalysis
- Organic chemistry
- Hydrogen
Hideshi Hattori mostly deals with Catalysis, Inorganic chemistry, Adsorption, Hydrogen and Organic chemistry.
His Catalysis research includes elements of Nitromethane and Reactivity.
His Inorganic chemistry research is multidisciplinary, incorporating perspectives in Methanol, Oxide and Lewis acids and bases.
His Adsorption study incorporates themes from Pyridine and Infrared spectroscopy.
His study focuses on the intersection of Hydrogen and fields such as Platinum with connections in the field of Hydrogen spillover and Physical chemistry.
His work on Ethyl acetate, Alcohol, Epoxide and Transesterification as part of general Organic chemistry study is frequently connected to Propylene oxide, therefore bridging the gap between diverse disciplines of science and establishing a new relationship between them.
This overview was generated by a machine learning system which analysed the scientist’s
body of work. If you have any feedback, you can
contact us
here.
