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Squeezing Light Through Small Holes

Squeezing Light Through Small Holes. Taco D. Visser. VU University Amsterdam. TexPoint fonts used in EMF: A A A A A A A. How much light is transmitted by a small aperture in a metal plate?. 10 mm. 2 mm. Metal. 10 incident rays.

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Squeezing Light Through Small Holes

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  1. Squeezing Light Through Small Holes Taco D. Visser VU University Amsterdam TexPoint fonts used in EMF: AAAAAAA

  2. How much light is transmitted by a small aperture in a metal plate? 10 mm 2 mm Metal 10 incident rays 20 % of the metal plate is open, so only 2 out of 10 rays can pass through. The others are reflected or absorbed. Geometrical optics predicts a transmission of 20%.

  3. But what about nano-holes? 100 nanometer 20 nanometer Metal For holes that are smaller than the wavelength geometrical optics is no longer valid. So what happens to the transmission? Is it still 20%?

  4. Extraordinary Optical Transmission T.W. Ebbesen et al., Nature 391, 1998. The round holes are 20% of the surface. But the transmission is more than 20%! How is this extraordinary transmission possible?

  5. Hole Shape Influences the Transmission Three types of holes: a. Circular holes, with an area of 28,000 nm2 b. Rectangular holes with an area of 16,000 nm2 c. Rectangular holes with an area of 32,000 nm2 Klein Koerkamp et al. Physical Review Letters 92, 2004.

  6. Influence of the hole shape • Surprisingly, at 900 nm the small rectangular holes transmits more light than the larger holes! Thisagain shows thatgeometricaloptics is not a good model forthissituation. • The circular holes alwaystransmitless.

  7. Slit in a Metal Plate Depending on the slit width w, zero, one, two or more guided modes can exist in the hole. Their number influences the transmission.

  8. A Scattering Approach • Split field into two parts: = field around metal plate without slit = scattered field due to slit 2. Convert Maxwell’s equation into an integral equation: 3. Solve integral equation numerically

  9. Transmission vs. Slit Width for Silver Plate T w/l Silver (n = 0.05 + i 2.87) l = 500 nm thickness = 100 nm Question: How can transmission be > 1 ?

  10. Effective index of first TE mode in silver When the width w = 0.4 l, the first TE mode kicks in.

  11. w = T= Power flow for Silver

  12. w = T= Annihilation

  13. More Topological Structures source sink vortex saddle monkey saddle dipole

  14. Many Annihilations If we increase the slit width a little, a host of structures annihilate, leading to a smoother power flow and thus an enhanced transmission This annihilation of vortices and saddle points coincides with the onset of the first guided mode PRE 67, 036608 (2003)

  15. Optical Vortices In the example of a narrow slit in a silver film, the vortices seem to concentrate the power flow and that way more light is `pushed through’ the slit than you would expect. But what happens when we change the material from a metal into a semiconductor such a silicon?

  16. Silver vs. Silicon T w/l red =silicon (n = 4.3 – i 0.74) blue= silver(n = 0.05 – i 2.87) l = 500 nm thickness = 100 nm Transmission for a slit in a silicon plate is less than expected.

  17. Changing the handedness of the vortices: Silicon • A narrow slit in a silicon plate has a low transmission, i.e. T<1 • it transmits less light than you would expect. • This anomalously low transmission coincides with a • changein handedness of the optical vortices (b and c) . • Notice the two saddles (a and d) and the two sinks. J. of Optics A 6, S277 (2004).

  18. Creating a monkey saddle • The two saddle points have joined to form a monkey saddle (e). • The two vortices (b and c) have moved sideways, but still push • the light “the wrong way.”

  19. Surface Plasmons - I • When an incident TM field hits the slit, surface plasmons are • generated. • They travel away from the slit to the left and to the right. • Eventually the plasmons are absorbed by the metal. surface plasmon surface plasmon incident TM wave

  20. Surface Plasmons - II • Until now we have only analyzed a single slit. • If we have two slits, are they independent? d Incident TM wave What is the influence of the two slits on each other?

  21. Surface Plasmons - III Transmitted plasmon field Incident TM wave • A part of the incident field at the left slit is converted into • surface plasmons that travel to the right. • There the surface plasmons can change back into a free field again. • The same thing happens at the right slit. • So, in each slit there are two fields: the directly transmitted field • and the surface plasmons from the other slit.

  22. Surface Plasmons Interference interference d incident TM wave • At each slit the total field consists of two contributions: • 1. The directly transmitted field. • 2. The surface plasmon field coming from the other slit. • The two fields can interfere in a constructive or in a • destructive manner.

  23. Changing the phase of the Surface Plasmons

  24. Plasmon Interference (changing d) Maximum intensity at the slits Minimum intensity at the slits

  25. Experiment (changing l) The total transmission varies strongly with the wavelength, just as predicted. Distance between slits = 25 mm, Width slit = 200 nm Thickness plate (gold) = 200 nm, TM polarization Phys. Rev. Lett., 94, 053901, 2005.

  26. Steering the Plasmons surface plasmon surface plasmon Surfaceplasmonsgenerated at the slittraveltoleftandto the right Can we control the direction in which the plasmons are launched? Until now only static schemes (built-in asymmetry) have been proposed. incident TM beam

  27. piezo A narrow slit in a gold film allows only two TM modes, one is symmetric (TM0), the other anti-symmetric (TM1). Beam B only excites the even mode. Beams A and –A have the same amplitude but are p phase shifted. Together they only excite the odd mode. By varying the phase of beam B with a piezo we can control the superposition of the two guided modes.

  28. --Total magnetic field on interface By tuning the superposition of the two modes we can get complete cancellation of the field at one side of the slit exit. Plasmons will only be generated on the opposite side: Unidirectional plasmon launching

  29. By simply changing the phase of the normally incident beam, we get dynamic plasmon switching Optics Express 20, 15326 (2012).

  30. Steering the Radiation Field The transmitted light is radiatedsymmetrically. Can we also control the direction of radiation? incident laser beam

  31. Minima of the far-zone radiation of a slit coincide with phase singularities in the near-field along the line of sight. Physical Review Letters, vol. 93, 173901 (2004).

  32. Using the same method of selective mode excitation, we can steer the radiation continuously from left to right by varying the voltage across the piezo.

  33. Two different voltage settings across the piezo give radiation to the left (blue) or to the right (red). Physical Review Letters, vol. 111, 153901 (2013).

  34. Conclusions The extraordinary transmission of light throughnano-apertures is accompaniedbyopticalvorticesthatfunnel the light. Very low transmission (as in silicon) is accompaniedbyopticalvorticessteering the light awayfrom the slit. The onset of guided modes is accompaniedby the annihilation of vorticesandsaddles. Surfaceplasmonsgenerated at one hole cantraveltoanother hole wheretheyinterferewith the directly incident field. Depending on the hole separationthiseither increases or decreases the transmission. There is a connectionbetween the direction of minimalradiation and the presence of phasesingularitiesnear the slit. By selective excitation of the guided modes we can dynamically steer both the plasmons and the radiated field. andfinally….

  35. Thanks to • ShreyasRaghunathan (Delft) • Hugo Schouten (Amsterdam) • Thomas van Dijk (Urbana Champain) • Greg Gbur (Charlotte) • WimUbachs (Amsterdam) • Erik Eliel (Leiden) • Dave Fischer (NASA, Cleveland) • PhillipeLalanne (Paris/Bordeaux)

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