D-Index & Metrics Best Publications

D-Index & Metrics

Discipline name D-index D-index (Discipline H-index) only includes papers and citation values for an examined discipline in contrast to General H-index which accounts for publications across all disciplines. Citations Publications World Ranking National Ranking
Engineering and Technology D-index 43 Citations 5,880 113 World Ranking 2140 National Ranking 869

Overview

What is he best known for?

The fields of study he is best known for:

  • Quantum mechanics
  • Thermodynamics
  • Mechanics

His scientific interests lie mostly in Mechanics, Molecule, Statistical physics, Microfluidics and Brownian dynamics. The study incorporates disciplines such as Mixing and Classical mechanics in addition to Mechanics. He interconnects Computer simulation and Reynolds number in the investigation of issues within Classical mechanics.

His work deals with themes such as Particle transport and Flow, which intersect with Statistical physics. Michael D. Graham works mostly in the field of Microfluidics, limiting it down to concerns involving Polymer and, occasionally, Chemical physics. His research in Brownian dynamics intersects with topics in Particle, Dynamics, Bifurcation diagram, Bifurcation and Stochastic differential equation.

His most cited work include:

  • Transport and collective dynamics in suspensions of confined swimming particles. (298 citations)
  • A single-molecule barcoding system using nanoslits for DNA analysis (268 citations)
  • Stochastic simulations of DNA in flow: Dynamics and the effects of hydrodynamic interactions (221 citations)

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

His primary scientific interests are in Mechanics, Classical mechanics, Turbulence, Shear flow and Drag. Michael D. Graham combines topics linked to Viscoelasticity with his work on Mechanics. His Classical mechanics study combines topics in areas such as Couette flow and Bifurcation.

His Turbulence research incorporates elements of Newtonian fluid and Nonlinear system. His Shear flow research includes themes of Slip, Brownian dynamics and Simple shear. His study looks at the intersection of Thermodynamics and topics like Polymer with Chemical physics and Molecule.

He most often published in these fields:

  • Mechanics (42.05%)
  • Classical mechanics (26.14%)
  • Turbulence (20.83%)

What were the highlights of his more recent work (between 2016-2021)?

  • Mechanics (42.05%)
  • Turbulence (20.83%)
  • Open-channel flow (11.74%)

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

Michael D. Graham mainly focuses on Mechanics, Turbulence, Open-channel flow, Reynolds number and Dynamics. His study in Mechanics focuses on Steady state in particular. His research in Turbulence intersects with topics in Drag, Flow, Newtonian fluid and Nonlinear system.

The Open-channel flow study combines topics in areas such as Weissenberg number and Viscoelasticity. His Reynolds number research integrates issues from Mathematical analysis, Curvature, Degree of curvature, Stability theory and Vortex. His studies deal with areas such as Flexibility and Classical mechanics as well as Bifurcation.

Between 2016 and 2021, his most popular works were:

  • Critical-Layer Structures and Mechanisms in Elastoinertial Turbulence (27 citations)
  • Low-drag events in transitional wall-bounded turbulence (16 citations)
  • Exact coherent states with hairpin-like vortex structure in channel flow (15 citations)

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

  • Quantum mechanics
  • Mechanics
  • Thermodynamics

Michael D. Graham mostly deals with Mechanics, Turbulence, Reynolds number, Drag and Open-channel flow. His Mechanics research includes elements of Shear and Bifurcation. His work in Bifurcation addresses subjects such as Thrust, which are connected to disciplines such as Classical mechanics.

His study in Turbulence is interdisciplinary in nature, drawing from both Newtonian fluid and Nonlinear system. His work focuses on many connections between Reynolds number and other disciplines, such as Vortex, that overlap with his field of interest in Traveling wave. He works mostly in the field of Open-channel flow, limiting it down to topics relating to Weissenberg number and, in certain cases, Plane.

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.

Best Publications

Transport and collective dynamics in suspensions of confined swimming particles.

Juan P. Hernandez-Ortiz;Christopher G. Stoltz;Michael D. Graham.
Physical Review Letters (2005)

409 Citations

A single-molecule barcoding system using nanoslits for DNA analysis

Kyubong Jo;Dalia M. Dhingra;Theo Odijk;Juan J. de Pablo.
Proceedings of the National Academy of Sciences of the United States of America (2007)

343 Citations

Stochastic simulations of DNA in flow: Dynamics and the effects of hydrodynamic interactions

Richard M. Jendrejack;Juan José de Pablo;Michael D. Graham.
Journal of Chemical Physics (2002)

334 Citations

Shear-induced migration in flowing polymer solutions: Simulation of long-chain DNA in microchannels

Richard M. Jendrejack;David C. Schwartz;Juan José de Pablo;Michael D. Graham.
Journal of Chemical Physics (2004)

283 Citations

DNA dynamics in a microchannel.

Richard M. Jendrejack;Eileen T. Dimalanta;David C. Schwartz;Michael D. Graham.
Physical Review Letters (2003)

222 Citations

Diffusion and Spatial Correlations in Suspensions of Swimming Particles

Patrick T. Underhill;Juan P. Hernandez-Ortiz;Michael D. Graham.
Physical Review Letters (2008)

215 Citations

A microfluidic system for large DNA molecule arrays.

Eileen T. Dimalanta;Alex Lim;Rod Runnheim;Casey Lamers.
Analytical Chemistry (2004)

212 Citations

Effect of confinement on DNA dynamics in microfluidic devices

Richard M. Jendrejack;David C. Schwartz;Michael D. Graham;Juan José de Pablo.
Journal of Chemical Physics (2003)

207 Citations

Hydrodynamic interactions in long chain polymers: Application of the Chebyshev polynomial approximation in stochastic simulations

Richard M. Jendrejack;Michael D. Graham;Juan José de Pablo.
Journal of Chemical Physics (2000)

205 Citations

Theory of shear-induced migration in dilute polymer solutions near solid boundaries

Hongbo Ma;Michael D. Graham.
Physics of Fluids (2005)

204 Citations

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