Use Nanoantennas in a sentence

1. Nanoantennas target the mid infrared wavelengths where conventional photo voltaic cells are inefficient

Nanoantennas

2. Also objects give off heat as infrared rays, Nanoantennas could collect those rays and re-emit energy at

Nanoantennas

3. Abstract Single-photon Nanoantennas are broadband strongly scattering nanostructures placed in the near field of a single quantum emitter, with the goal to enhance the coupling between the emitter and far-field radiation channels.

Nanoantennas, Nanostructures, Near

4. In an article in Nature Nanotechnology, scientists from Linköping University present optical Nanoantennas, made from a conducting polymer instead …

Nature, Nanotechnology, Nanoantennas

5. Scientists slow and steer light with resonant Nanoantennas by Lara Streiff, Stanford University An artist rendering of a high-Q metasurface beamsplitter

Nanoantennas

6. The directionality of the Nanoantennas stems from their electromagnetic resonance properties or the interference between different resonance modes. The near‐field interaction between the Nanoantennas and fluorescent emitters or Raman molecules will …

Nanoantennas, Near

7. Here, we introduce addressable Nanoantennas with Cleared HOtSpots (NACHOS) that are scaffolded by DNA origami nanostructures and can be …

Nanoantennas, Nachos, Nanostructures

8. Abstract and Figures Optical Nanoantennas, i.e., elements transforming localized light or waveguide modes into freely propagating fields and vice versa, are vital components for modern

Nanoantennas

9. Abstract Plasmonic Nanoantennas are promising sensing platforms for detecting chemical and biological molecules in the infrared region

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10. However, integrating fragile biological molecules such as proteins on plasmonic Nanoantennas is an essential requirement in the detection procedure.

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11. Nanoantennas for visible and infrared radiation can strongly enhance the interaction of light with nanoscale matter by their ability to efficiently link propagating and spatially localized optical fields

Nanoantennas, Nanoscale

12. Abstract Plasmonic Nanoantennas allow the efficient conversion of impinging optical radiation from the far-field into confined, strongly enhanced fields at the nanoscale or, by reciprocity, the coupling of localized optical sources to far-field radiation.

Nanoantennas, Nanoscale

13. Studies of plasmonic Nanoantennas suggest a high level of their dissipation losses, especially when the distance between metallic nanoelements is smaller than their characteristic size

Nanoantennas, Nanoelements

14. "The Nanoantennas are tiny gold squares or spirals set in a specially treated form of polyethylene, a material used in plastic bags

Nanoantennas

15. Plasmonic Nanoantennas: fundamentals and their use in controlling the radiative properties of nanoemitters Chem Rev

Nanoantennas, Nanoemitters

16. In conclusion, we have demonstrated an ultrafast spontaneous emission source with an emission speed exceeding 11 ps from a hybrid system consisting of plasmonic Nanoantennas coupled to …

Nanoantennas

17. Several Nanoantennas’ configurations are placed on different areas of the resonator

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18. • The use of Nanoantennas to tune the response of a ring resonator

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19. • Quality-factor, bandwidth and extinction ratio can be improved, using Nanoantennas

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20. Optical Nanoantennas are emerging as one of the key components in the future nanophotonic and plasmonic circuits

Nanoantennas, Nanophotonic

21. The first optical Nanoantennas were in a form of simple spherical nanoparticles

Nanoantennas, Nanoparticles

22. These Nanoantennas enhance radiation of single emitters and provide well-defined directional radiation.

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23. A particularly interesting feature of dielectric Nanoantennas is the possibility to integrate them in optical resonators with high quality-factor, further improving the performance of the

Nanoantennas

24. Nanoantenna (plural Nanoantennas or nanoantennae) A nanoscale antenna -like structure for sending and transmitting electromagnetic waves.

Nanoantenna, Nanoantennas, Nanoantennae, Nanoscale

25. These Nanoantennas are installed on top of a transparent wafer base, constructed from sapphire in the experimental setup

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26. Abstract Optical Nanoantennas provide a promising pathway toward advanced manipulation of light waves, such as directional scattering, …

Nanoantennas

27. In an article published today (December 9, 2019) in Nature Nanotechnology, scientists from Linköping University present optical Nanoantennas, made from a conducting polymer instead of a traditional metal, such as gold or silver.In this case, they used a variant of PEDOT, which is a widely used polymer in many other areas, including thermoelectrics and bioelectronics.

Nature, Nanotechnology, Nanoantennas

28. The steerable Nanoantennas can find applications in areas such as tunable on chip plasmonic interconnects, networks on chip, or for selective excitation of fluorophores on a sensor chip.

Nanoantennas, Networks

29. Furthermore, compared to the Au-based high-loss plasmonic Nanoantennas, Si-based low-loss structures would generate negligible photothermal effect, which makes Si Nanoantennas an optimized candidate to amplify molecular CD signals with ultralow thermal damage.

Nanoantennas, Negligible

30. We theoretically investigate light-matter interactions for chiral molecules in the presence of nonchiral Nanoantennas

Nonchiral, Nanoantennas

31. Metallic-tip Nanoantennas of this kind have been used to study the fluorescence or Raman scattering of nanometer-scale objects (7–9)

Nanoantennas, Nanometer

32. The next step is to improve the design and the performance of the Nanoantennas

Next, Nanoantennas

33. The Nanoantennas are V-shaped structures made of gold and formed on top of a silicon layer

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34. We demonstrate that the emission of light by fluorescent molecules in the proximity of periodic arrays of Nanoantennas or plasmonic crystals can be strongly modified when the arrays are covered by a dielectric film

Nanoantennas

35. The inclusion of Nanoantennas provides the device with an additional advantage: the ability to tailor which type of light it is sensitive to by etching a different pattern of slots on the surface

Nanoantennas

36. V-type Nanoantennas placed on a conducting ground layer, which can effectively mitigate the plasmonic heating effect and thus enable subwavelength plasmonic trapping in the near-infrared region

Nanoantennas, Near

37. A rigorous theory of photon emission generated by inelastic electron tunnelling inside the gap of plasmonic Nanoantennas is developed

Nanoantennas

38. What does Nanoantennas mean? Plural form of nanoantenna

Nanoantennas, Nanoantenna

39. Nanoantennas and Plasmonics: Modelling, design and fabrication (Electromagnetic Waves) by Douglas H

Nanoantennas

40. Detecting individual biomarkers is a particular application of high-Q Nanoantennas

Nanoantennas

41. The gold Nanoantennas are so small they aren’t visible on top of the detector array

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42. Nanoantennas can take in energy from both sunlight and the earth's heat, with higher efficiency than conventional solar cells

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43. Nanoantennas after fabrication in an alumina template and after template removal, respectively

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44. Typically, the fabricated Nanoantennas exhibited rounded or cone-shaped gold segments on the top side due to shadowing by the template pore walls during the …

Nanoantennas

45. Nanoantennas rotating in opposite directions as shown in Figure 3 (two subarrays in blue and red)

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46. In this chapter, we show how terahertz Nanoantennas

Nanoantennas

47. Stanford scientists slow and steer light with resonant Nanoantennas

Nanoantennas

48. Researchers have fashioned ultrathin silicon Nanoantennas that trap and redirect light, for applications in quantum computing, LIDAR and even the detection of viruses

Nanoantennas