J
John M Gorman
Researcher at University of Minnesota
Publications - 71
Citations - 1176
John M Gorman is an academic researcher from University of Minnesota. The author has contributed to research in topics: Fluid dynamics & Turbulence. The author has an hindex of 16, co-authored 70 publications receiving 963 citations. Previous affiliations of John M Gorman include University of St. Thomas (Minnesota).
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A review of global ocean temperature observations: Implications for ocean heat content estimates and climate change
John Abraham,Molly O. Baringer,Nathaniel L. Bindoff,Nathaniel L. Bindoff,Nathaniel L. Bindoff,Timothy P. Boyer,Lijing Cheng,John A. Church,Jessica L. Conroy,Catia M. Domingues,John T. Fasullo,John Gilson,Gustavo Goni,Simon A. Good,John M Gorman,Viktor Gouretski,Masayoshi Ishii,Gregory C. Johnson,Shoichi Kizu,John M. Lyman,John M. Lyman,Alison M. Macdonald,W. J. Minkowycz,S. E. Moffitt,Matthew D. Palmer,Alberto R. Piola,Franco Reseghetti,Karina von Schuckmann,Kevin E. Trenberth,Isabella Velicogna,Isabella Velicogna,Joshua K. Willis +31 more
TL;DR: The evolution of ocean temperature measurement systems is presented with a focus on the development and accuracy of two critical devices in use today (expendable bathythermographs and conductivity-temperature-depth instruments used on Argo floats).
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Modeling and numerical simulation of the forces acting on a sphere during early-water entry
TL;DR: In this article, a model and simulation for the entry of a sphere into a water surface from an air space above the surface is presented, and the model is validated by comparison with extensive experimental data and with trends from approximate analyses.
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Rationalization of thermal injury quantification methods: Application to skin burns
TL;DR: It was demonstrated that values of CEM43 at the basal layer of the skin were highly correlated with the depth of injury calculated from a thermal injury integral, and it was shown that the cell survival/CEM43 relationship for the cases investigated here most closely aligns with isothermal exposure of tissue to temperatures of ~50 °C.
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A mass transfer model of temporal drug deposition in artery walls
TL;DR: A new mass transfer model has been formulated and implemented for predicting the penetration of liquid medication into an arterial wall and found that the drug concentration at a clinically relevant depth in the artery wall varied linearly with the duration of the therapy, increased with increasing values of the driving pressure, and decreased for higher viscosities of the advecting fluid.