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From: Quantum mechanism of light transmission by the intermediate filaments in some specialized optically transparent cells Neurophoton. 2016;4(1):011005.

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Presentation on theme: "From: Quantum mechanism of light transmission by the intermediate filaments in some specialized optically transparent cells Neurophoton. 2016;4(1):011005."— Presentation transcript:

1 From: Quantum mechanism of light transmission by the intermediate filaments in some specialized optically transparent cells Neurophoton. 2016;4(1): doi: /1.NPh Figure Legend: (a) Endfeet (red arrows) and basal processes (green arrows) of MCs in the Pied flycatcher retina. (b) High magnification insert from (a), showing a part of cytoplasmic structure (green arrows) that has parallel linear elements resembling IFs. This structure spans the cytoplasm from the narrow part of the basal endfoot to the apical end that wraps around a cone photoreceptor, in the direction of light transmission. Scale bar in (a) and (b)  is 500 nm. (c) Schematic presentation of the MCs (green arrows) with their endfeet (red arrows) and the cone photoreceptors (R, G, B). The light propagation direction coincides with the red arrows. Date of download: 9/19/ Copyright © 2016 SPIE. All rights reserved.

2 From: Quantum mechanism of light transmission by the intermediate filaments in some specialized optically transparent cells Neurophoton. 2016;4(1): doi: /1.NPh Figure Legend: Schematic presentation of the input section of the lightguide with a nanothick conductive wall. P is the Poynting vector, E is the electric field vector of the incident EMF, H is its magnetic field vector. Date of download: 9/19/ Copyright © 2016 SPIE. All rights reserved.

3 From: Quantum mechanism of light transmission by the intermediate filaments in some specialized optically transparent cells Neurophoton. 2016;4(1): doi: /1.NPh Figure Legend: The model for qualitative analysis. The waveguide is composed of a tube and two cones, with conductive walls. Date of download: 9/19/ Copyright © 2016 SPIE. All rights reserved.

4 From: Quantum mechanism of light transmission by the intermediate filaments in some specialized optically transparent cells Neurophoton. 2016;4(1): doi: /1.NPh Figure Legend: The model for numerical analysis, showing a cross section of the waveguide with conductive walls. R is the curvature radius referred to in Fig. 5 and 6. Date of download: 9/19/ Copyright © 2016 SPIE. All rights reserved.

5 From: Quantum mechanism of light transmission by the intermediate filaments in some specialized optically transparent cells Neurophoton. 2016;4(1): doi: /1.NPh Figure Legend: Calculated plots of the transmission efficiency η on the curvature radius R (see Fig. 4). The values of the variable model parameters are: ρ=10  nm, (1) r0=5ρ, (2) r0=10ρ, (3) r0=15ρ, and (4) r0=20ρ. Date of download: 9/19/ Copyright © 2016 SPIE. All rights reserved.

6 From: Quantum mechanism of light transmission by the intermediate filaments in some specialized optically transparent cells Neurophoton. 2016;4(1): doi: /1.NPh Figure Legend: Calculated plots of the transmission efficiency η on the curvature radius R (see Fig. 4). The values of the variable model parameters are: ρ=0.5  nm, (1) r0=5ρ, (2) r0=10ρ, (3) r0=15ρ, and (4) r0=20ρ. Date of download: 9/19/ Copyright © 2016 SPIE. All rights reserved.

7 From: Quantum mechanism of light transmission by the intermediate filaments in some specialized optically transparent cells Neurophoton. 2016;4(1): doi: /1.NPh Figure Legend: Calculated test absorption spectrum for device shown in Fig. 4, where the device parameters are: r0=25  nm, ρ=4  nm, L1=10  μm, L2=9  μm, R=0.5  μm. Date of download: 9/19/ Copyright © 2016 SPIE. All rights reserved.


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