Composite material, Ionomer, Carbon nanotube, Membrane and Finite element method are his primary areas of study. His study in Shear, Contact area and Rheology is carried out as part of his studies in Composite material. In the field of Carbon nanotube, his study on Nanotube overlaps with subjects such as Transmission electron micrograph.
As a part of the same scientific family, James A. Elliott mostly works in the field of Membrane, focusing on Side chain and, on occasion, Polymer chemistry, Sulfonic acid and Dissipative particle dynamics. His Finite element method research includes elements of Bending, Compression, Compaction and Forensic engineering. James A. Elliott has included themes like Chemical physics and Small-angle X-ray scattering, Scattering in his Ionic bonding study.
James A. Elliott focuses on Composite material, Carbon nanotube, Chemical engineering, Nanotechnology and Compaction. His Composite material study combines topics from a wide range of disciplines, such as Finite element method and Particle size. James A. Elliott is interested in Nanotube, which is a field of Carbon nanotube.
His Chemical engineering study integrates concerns from other disciplines, such as Membrane and Polymer chemistry. His work is dedicated to discovering how Polymer chemistry, Side chain are connected with Molecule and Crystallography and other disciplines. The Compaction study combines topics in areas such as Granular material, Discrete element method, Mechanics and Shear.
James A. Elliott spends much of his time researching Carbon nanotube, Composite material, Chemical engineering, Statistical physics and Dissipative particle dynamics. His Carbon nanotube research incorporates themes from Bundle, Ginzburg landau and Raman spectroscopy. The study incorporates disciplines such as Torsion spring, Diffraction and Anisotropy in addition to Composite material.
His research in Chemical engineering intersects with topics in Yield, Flow and Chemical vapor deposition. His Statistical physics study incorporates themes from Density functional theory and Ground state. His work in Dissipative particle dynamics addresses subjects such as Surface tension, which are connected to disciplines such as Force field and Complex fluid.
His primary areas of investigation include Carbon nanotube, Raman spectroscopy, Chemical engineering, Composite material and Chemical vapor deposition. His Carbon nanotube study combines topics in areas such as Solid-state physics, Statistical physics and Ground state. His Raman spectroscopy research is multidisciplinary, relying on both Thermogravimetric analysis and Volumetric flow rate.
His work carried out in the field of Thermogravimetric analysis brings together such families of science as Fiber, Graphite, Nanotube and Intercalation. His work deals with themes such as Yield, Carbon, Atomic carbon and Operating temperature, which intersect with Chemical engineering. As part of his studies on Composite material, James A. Elliott frequently links adjacent subjects like Diffraction.
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