![DTI Processing - Voxel-based versus tract-based diffusion imaging | Diffusion Imaging; Introduction, tutorials and background on diffusion tensor imaging and techniques DTI Processing - Voxel-based versus tract-based diffusion imaging | Diffusion Imaging; Introduction, tutorials and background on diffusion tensor imaging and techniques](https://1.bp.blogspot.com/-YO3h0cRqTEc/UIRKEC_0N8I/AAAAAAAABQs/dEPzCbcyuCo/s1600/FA_tensor.png)
DTI Processing - Voxel-based versus tract-based diffusion imaging | Diffusion Imaging; Introduction, tutorials and background on diffusion tensor imaging and techniques
![a) Transition from radial to linear diffusion regimes with increasing... | Download Scientific Diagram a) Transition from radial to linear diffusion regimes with increasing... | Download Scientific Diagram](https://www.researchgate.net/publication/343896292/figure/fig5/AS:1042213148581904@1625494386655/a-Transition-from-radial-to-linear-diffusion-regimes-with-increasing-y-Randles-Sevcik.png)
a) Transition from radial to linear diffusion regimes with increasing... | Download Scientific Diagram
![SOLVED: The diffusion equation for a long cylinder in which diffusion is everywhere radial can be represented by: ∂C/∂t = D(1/r)(∂/∂r)(r∂C/∂r) Here C is the concentration and r is the radial coordinate. SOLVED: The diffusion equation for a long cylinder in which diffusion is everywhere radial can be represented by: ∂C/∂t = D(1/r)(∂/∂r)(r∂C/∂r) Here C is the concentration and r is the radial coordinate.](https://cdn.numerade.com/ask_images/926cd4fbfb834a15a53099b903d8b710.jpg)
SOLVED: The diffusion equation for a long cylinder in which diffusion is everywhere radial can be represented by: ∂C/∂t = D(1/r)(∂/∂r)(r∂C/∂r) Here C is the concentration and r is the radial coordinate.
![Figure 2.8 from Modeling Earth's Outer Radiation Belt Electron Dynamics---Radial Diffusion, Heating, and Loss | Semantic Scholar Figure 2.8 from Modeling Earth's Outer Radiation Belt Electron Dynamics---Radial Diffusion, Heating, and Loss | Semantic Scholar](https://d3i71xaburhd42.cloudfront.net/dff1b314127293cb7a9473a33392ee95c31b90d0/41-Figure2.8-1.png)
Figure 2.8 from Modeling Earth's Outer Radiation Belt Electron Dynamics---Radial Diffusion, Heating, and Loss | Semantic Scholar
![Radial Diffusion and Penetration of Gas Molecules and Aerosol Particles through Laminar Flow Reactors, Denuders, and Sampling Tubes | Analytical Chemistry Radial Diffusion and Penetration of Gas Molecules and Aerosol Particles through Laminar Flow Reactors, Denuders, and Sampling Tubes | Analytical Chemistry](https://pubs.acs.org/cms/10.1021/ac5042395/asset/images/medium/ac-2014-042395_0010.gif)
Radial Diffusion and Penetration of Gas Molecules and Aerosol Particles through Laminar Flow Reactors, Denuders, and Sampling Tubes | Analytical Chemistry
![Illustrating Axial Diffusion, Radial Diffusion and Fractional Diffusion [8] | Download Scientific Diagram Illustrating Axial Diffusion, Radial Diffusion and Fractional Diffusion [8] | Download Scientific Diagram](https://www.researchgate.net/publication/337462013/figure/fig1/AS:828226603597824@1574476018741/Illustrating-Axial-Diffusion-Radial-Diffusion-and-Fractional-Diffusion-8.png)