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Slot waveguides

Fig. 8.24 (a) Schematic of a curved slot waveguide (b) E field distribution of a straight polysty rene slot waveguide is shown with total waveguide width of 2.6 pm including a slot of 200 nm wide (TE polarization). The inset curve is the field magnitude at Y 3 pm, which indicates stronger E field within the slot... [Pg.204]

Baehr Jones, T. Hochberg, M. Walker, C. Scherer, A., High Q optical resonators in silicon on insulator based slot waveguides, Appl. Phys. Lett. 2005, 86, 081101... [Pg.228]

Figure 9.8 shows a variant of the silicon photonic wire waveguide known as a slot waveguide, which has attracted considerable recent interest43 5. The structure consists of two parallel Si channel waveguides separated by a narrow gap. Here almost the entire mode field is concentrated in the gap between the two... [Pg.241]

Fig. 9.8 Cross section of a silicon slot waveguide consisting of two 180 nm x 250 nm silicon channels, separated by a 50 nm gap. The solid line represents a line plot of the electric field amplitude of the horizontally polarized TE mode, taken along the horizontal midline of the waveguide... Fig. 9.8 Cross section of a silicon slot waveguide consisting of two 180 nm x 250 nm silicon channels, separated by a 50 nm gap. The solid line represents a line plot of the electric field amplitude of the horizontally polarized TE mode, taken along the horizontal midline of the waveguide...
Fig. 2 Total-internal reflection (TIR) based waveguides, (a) TIR principle of ray propagating in core medium with index c. surrounded by cladding with index nci. (b) LCWG, (c) nanoporous cladding waveguide, (d) liquid-liquid (L ) waveguide, (e) slot waveguide... Fig. 2 Total-internal reflection (TIR) based waveguides, (a) TIR principle of ray propagating in core medium with index c. surrounded by cladding with index nci. (b) LCWG, (c) nanoporous cladding waveguide, (d) liquid-liquid (L ) waveguide, (e) slot waveguide...
The recently proposed and demonstrated slot waveguide is an alternative in which index guiding can be realized in nanoscale cross sections, thereby providing an... [Pg.201]

Fig. 1 Various ring resonator sensor configurations, (a) Microsphere, (b) Silicon-on-insulator planar ring resonator, (c) Slot waveguide ring resonator, (d) Planar disc ring resonator, (e) Glass planar ring array, (f) Microtoroid, (g) Microknot, (h) Opto-fluidic ring resonator (OFRR) and the inset is the SEM image of the OFRR cross-section. Reprinted with permissions from refs [13, 28, 30, 32, 50, 53, 70, 86]... Fig. 1 Various ring resonator sensor configurations, (a) Microsphere, (b) Silicon-on-insulator planar ring resonator, (c) Slot waveguide ring resonator, (d) Planar disc ring resonator, (e) Glass planar ring array, (f) Microtoroid, (g) Microknot, (h) Opto-fluidic ring resonator (OFRR) and the inset is the SEM image of the OFRR cross-section. Reprinted with permissions from refs [13, 28, 30, 32, 50, 53, 70, 86]...
Barrios CA, Gylfason KB, Sanchez B et al (2007) Slot-waveguide biochemical sensor. Gpt Lett 32 3080-3082... [Pg.276]

Barrios CA, Banuls MJ, Gonz ez-Pedro V et al (2008) Label-free optical biosensing with slot-waveguides. Gpt Lett 33 708-710... [Pg.276]

Figure 10. Silicon Slot waveguide trapping structure, (a) Schematic of waveguide, (b) mode profile showing trapping location. Figure 10. Silicon Slot waveguide trapping structure, (a) Schematic of waveguide, (b) mode profile showing trapping location.
Figure 11. Trapping of nanoparticles inside a silicon Slot Waveguide. (a) SEM of 100 nm wide slot waveguide, (b-d) Demonstration of trapping and release of 75 nm dielectric nanoparticles from inside slot. These experiments were conducted with approximate 100 mW of excitation power at 1,550 nm. Figure 11. Trapping of nanoparticles inside a silicon Slot Waveguide. (a) SEM of 100 nm wide slot waveguide, (b-d) Demonstration of trapping and release of 75 nm dielectric nanoparticles from inside slot. These experiments were conducted with approximate 100 mW of excitation power at 1,550 nm.
Figure 12. Capture and trapping of 7,-DNA. Images show individual YOYO tagged 48 kBb X-DNA trapped and released over a 60 mn slot waveguide. Figure 12. Capture and trapping of 7,-DNA. Images show individual YOYO tagged 48 kBb X-DNA trapped and released over a 60 mn slot waveguide.
C. A. Banios and M. Lipson, Electrically driven silicon resonant light emitting device based on slot- waveguide. Optics Express 13 p. 10092-10101 (2005). [Pg.551]

A. Yang, S. Moore, B. Schmidt, M. King, M. Lipson, andD. Erickson, Optical manipulation of nanoparticles and biomolecules in sub-wavelength slot waveguides. Nature, Accepted (2008). [Pg.551]

OhI A 1998 Fundamentals and limitations of large area planar microwave discharges using slotted waveguides J. Physique IV 8 Pr7 83-98... [Pg.2812]


See other pages where Slot waveguides is mentioned: [Pg.2803]    [Pg.4]    [Pg.202]    [Pg.204]    [Pg.204]    [Pg.206]    [Pg.226]    [Pg.228]    [Pg.242]    [Pg.257]    [Pg.263]    [Pg.548]    [Pg.258]    [Pg.263]    [Pg.201]    [Pg.202]    [Pg.265]    [Pg.266]    [Pg.187]    [Pg.529]    [Pg.545]    [Pg.546]    [Pg.547]    [Pg.2803]    [Pg.47]    [Pg.178]    [Pg.1804]   
See also in sourсe #XX -- [ Pg.202 , Pg.204 , Pg.206 , Pg.241 , Pg.242 , Pg.257 , Pg.488 ]




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