What is he best known for?
The fields of study he is best known for:
- Thermodynamics
- Mechanics
- Viscosity
Mechanics, Reynolds number, Newtonian fluid, Classical mechanics and Polymer are his primary areas of study.
His studies deal with areas such as Rheometer, Rheology, Mixing, Strain rate and Viscoelasticity as well as Mechanics.
His studies in Reynolds number integrate themes in fields like Instability, Gait, Viscosity, Material properties and Microchannel.
His Newtonian fluid study incorporates themes from Non-Newtonian fluid, Suspension, Steady state and Active matter.
The study incorporates disciplines such as Elasticity, Elastic instability, Bifurcation and Velocimetry in addition to Classical mechanics.
His Polymer research is multidisciplinary, relying on both Flow, Vector field, Microbiology and Rotational diffusion.
His most cited work include:
- Elastic Instabilities of Polymer Solutions in Cross-Channel Flow (162 citations)
- Elastic Instabilities of Polymer Solutions in Cross-Channel Flow (162 citations)
- Rheology of human blood plasma: viscoelastic versus Newtonian behavior. (137 citations)
What are the main themes of his work throughout his whole career to date?
His primary areas of investigation include Mechanics, Chemical physics, Reynolds number, Classical mechanics and Rheology.
His research investigates the link between Mechanics and topics such as Viscoelasticity that cross with problems in Elasticity.
The various areas that he examines in his Chemical physics study include Suspension and Particle size.
His Reynolds number study deals with Mathematical analysis intersecting with Lyapunov exponent and Chaotic mixing.
Paulo E. Arratia interconnects Colloid and Microfluidics, Nanotechnology in the investigation of issues within Rheology.
In his research, Velocimetry is intimately related to Viscosity, which falls under the overarching field of Newtonian fluid.
He most often published in these fields:
- Mechanics (41.26%)
- Chemical physics (16.50%)
- Reynolds number (17.48%)
What were the highlights of his more recent work (between 2018-2021)?
- Mechanics (41.26%)
- Chemical physics (16.50%)
- Flow (15.05%)
In recent papers he was focusing on the following fields of study:
Paulo E. Arratia mostly deals with Mechanics, Chemical physics, Flow, Rheology and Amorphous solid.
His Mechanics research is multidisciplinary, incorporating perspectives in Cylinder, Viscoelasticity and Time periodic.
He usually deals with Viscoelasticity and limits it to topics linked to Instability and Inflow, Vortex ring and Stress.
Paulo E. Arratia has researched Flow in several fields, including Cross slot and Inertial frame of reference.
His work on Oscillatory shear as part of general Rheology study is frequently linked to Local structure, therefore connecting diverse disciplines of science.
In his research on the topic of Reynolds number, Volumetric flow rate is strongly related with Newtonian fluid.
Between 2018 and 2021, his most popular works were:
- Upstream vortex and elastic wave in the viscoelastic flow around a confined cylinder (19 citations)
- Quenching active swarms: effects of light exposure on collective motility in swarming Serratia marcescens. (12 citations)
- Formation of stable aggregates by fluid-assembled solid bridges (10 citations)
In his most recent research, the most cited papers focused on:
- Thermodynamics
- Mechanics
- Viscosity
His primary scientific interests are in Mechanics, Viscoelasticity, Reynolds number, Plasticity and Amorphous solid.
Paulo E. Arratia interconnects Flow, Wake, Drag and Instability in the investigation of issues within Viscoelasticity.
His research integrates issues of Stress, Inflow and Vortex ring in his study of Flow.
His study in Reynolds number is interdisciplinary in nature, drawing from both Non-Newtonian fluid, Shear flow, Volumetric flow rate and Newtonian fluid.
His work carried out in the field of Plasticity brings together such families of science as Rheometer, Rheology, Shearing, Dissipation and Microstructure.
His Amorphous solid research integrates issues from Monolayer, Strain rate, Condensed matter physics and Shear rate.
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