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Water Entry of Projectiles: Supplemental Video 11
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Water entry shown in Figure 7a.
Water Entry of Projectiles: Supplemental Video 12
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Water entry shown in Figure 7b.
Water Entry of Projectiles: Supplemental Video 13
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Water entry shown in Figure 7c.
Water Entry of Projectiles: Supplemental Video 14
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Water entry shown in Figure 8a top row.
Water Entry of Projectiles: Supplemental Video 15
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Water entry shown in Figure 8a bottom row.
Water Entry of Projectiles: Supplemental Video 16
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Water entry shown in Figure 8b top row.
Water Entry of Projectiles: Supplemental Video 17
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Water entry shown in Figure 8b bottom row.
Water Entry of Projectiles: Supplemental Video 18
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Impact shown in Figure 9 top row.
Water Entry of Projectiles: Supplemental Video 19
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Impact shown in Figure 9 center row.
Water Entry of Projectiles: Supplemental Video 20
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Impact shown in Figure 9 bottom row.
Water Entry of Projectiles: Supplemental Video 21
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Water entry shown in Figure 12a.
Water Entry of Projectiles: Supplemental Video 22
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Water entry shown in Figure 12b.
Water Entry of Projectiles: Supplemental Video 23
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Color video of a modified 0.22-caliber bullet entry.
Water Entry of Projectiles: Supplemental Video 24
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Color video of a standard 0.22-caliber bullet entry.
Water Entry of Projectiles: Supplemental Video 25
A supplemental video from the 2014 review by Tadd T. Truscott Brenden P. Epps and Jesse Belden "Water Entry of Projectiles" from the Annual Review of Fluid Mechanics.
Water entry shown in Figure 13.
Fast Pressure-Sensitive Paint for Flow and Acoustic Diagnostics: Supplemental Video 2
A supplemental video from the 2014 review by James W. Gregory Hirotaka Sakaue Tianshu Liu and John P. Sullivan "Fast Pressure-Sensitive Paint for Flow and Acoustic Diagnostics" from the Annual Review of Fluid Mechanics.
Anodized aluminum pressure-sensitive paint (AA-PSP) measurements of a microscale fluidic oscillator flow oscillating at 9.4 kHz. Note that the jet width is 325 μm and the length scale of the flow field is approximately 2 mm × 2 mm highlighting the spatial resolution characteristics of pressure-sensitive paint.
Fast Pressure-Sensitive Paint for Flow and Acoustic Diagnostics: Supplemental Video 3
A supplemental video from the 2014 review by James W. Gregory Hirotaka Sakaue Tianshu Liu and John P. Sullivan "Fast Pressure-Sensitive Paint for Flow and Acoustic Diagnostics" from the Annual Review of Fluid Mechanics.
Temperature-insensitive anodized aluminum pressure-sensitive paint (AA-PSP) pressure data on a 30° compression corner model at Mach 7.1. Despite strong time-varying temperature gradients in this short-duration flow the AA-PSP was able to faithfully reproduce the pressure distribution.
Fast Pressure-Sensitive Paint for Flow and Acoustic Diagnostics: Supplemental Video 4
A supplemental video from the 2014 review by James W. Gregory Hirotaka Sakaue Tianshu Liu and John P. Sullivan "Fast Pressure-Sensitive Paint for Flow and Acoustic Diagnostics" from the Annual Review of Fluid Mechanics.
Map of the power spectral density at 108 Hz from anodized aluminum pressure-sensitive paint (AA-PSP) data on a transonic civil aircraft wing at M = 0.875.
Fast Pressure-Sensitive Paint for Flow and Acoustic Diagnostics: Supplemental Video 5
A supplemental video from the 2014 review by James W. Gregory Hirotaka Sakaue Tianshu Liu and John P. Sullivan "Fast Pressure-Sensitive Paint for Flow and Acoustic Diagnostics" from the Annual Review of Fluid Mechanics.
Map of pressure coefficients on a rocket fairing model in unsteady transonic flow.
A Lecture in Plant Biology: The Endodermis
Niko Geldner Assistant Professor of Plant Cell Biology at the University of Lausanne talks about his article "The Endodermis" which he wrote for the 2013 Annual Review of Plant Biology. The need for multicellular organisms to protect their inner extracellular space led the organisms to develop a diffusion barrier that can remain as selective as the hydrophobic plasma membrane of cells. In animal biology this barrier is known as the polarized epithelium which absorbs nutrients but keeps pathogens and excess away. In this lecture Dr. Geldner discusses the endodermis the plant variant of the polarized epithelium. Located on the plants' roots it has been a feature of ferns and angiosperms for approximately 400 million years.