Many of his studies on Artificial intelligence apply to Artificial neural network and Crossover as well. His work often combines Artificial neural network and Artificial intelligence studies. Michael D. Graham undertakes multidisciplinary investigations into Composite material and Polymer in his work. He performs multidisciplinary study on Polymer science and Polymer in his works. Michael D. Graham combines Generalization and Statistics in his research. Statistics and Generalization are two areas of study in which Michael D. Graham engages in interdisciplinary research. Bubble point is closely attributed to Bubble in his study. Michael D. Graham undertakes multidisciplinary investigations into Bubble and Parallel computing in his work. His Parallel computing study frequently draws connections between related disciplines such as Bubble point.
His study on Geometry is mostly dedicated to connecting different topics, such as Flow (mathematics), Scaling, Plane (geometry) and Block (permutation group theory). His studies link Mechanics with Flow (mathematics). Mechanics is closely attributed to Drag in his research. His research on Scaling often connects related areas such as Geometry. Michael D. Graham is involved in relevant fields of research such as Shear flow, Hinge and Kinetic energy in the domain of Classical mechanics. Michael D. Graham undertakes interdisciplinary study in the fields of Shear flow and Rheology through his works. He performs integrative Rheology and Shear rate research in his work. His Classical mechanics research extends to Hinge, which is thematically connected. He conducted interdisciplinary study in his works that combined Kinetic energy and Quantum mechanics.
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Transport and collective dynamics in suspensions of confined swimming particles.
Juan P. Hernandez-Ortiz;Christopher G. Stoltz;Michael D. Graham.
Physical Review Letters (2005)
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)
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)
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)
Diffusion and Spatial Correlations in Suspensions of Swimming Particles
Patrick T. Underhill;Juan P. Hernandez-Ortiz;Michael D. Graham.
Physical Review Letters (2008)
DNA dynamics in a microchannel.
Richard M. Jendrejack;Eileen T. Dimalanta;David C. Schwartz;Michael D. Graham.
Physical Review Letters (2003)
A microfluidic system for large DNA molecule arrays.
Eileen T. Dimalanta;Alex Lim;Rod Runnheim;Casey Lamers.
Analytical Chemistry (2004)
Theory of shear-induced migration in dilute polymer solutions near solid boundaries
Hongbo Ma;Michael D. Graham.
Physics of Fluids (2005)
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)
Alternative approaches to the Karhunen-Loève decomposition for model reduction and data analysis
Michael D. Graham;Ioannis G. Kevrekidis.
Computers & Chemical Engineering (1996)
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