Nanophotonics researchers pursue a very wide variety of goals, in fields ranging from biochemistry to electrical engineering to carbon-free energy. A few of these goals are summarized below.
Optoelectronics and microelectronics If light can be squeezed into a small volume, it can be absorbed and detected by a small detector. Small
photodetectors tend to have a variety of desirable properties including low noise, high speed, and low voltage and power. Small
lasers have various desirable properties for
optical communication including low threshold current (which helps power efficiency) and fast modulation (which means more data transmission). Very small lasers require
subwavelength optical cavities. An example is
spasers, the
surface plasmon version of lasers. Integrated circuits are made using
photolithography, i.e. exposure to light. In order to make very small transistors, the light needs to be focused into extremely sharp images. Using various techniques such as
immersion lithography and phase-shifting
photomasks, it has indeed been possible to make images much finer than the wavelength—for example, drawing 30 nm lines using 193 nm light. Plasmonic techniques have also been proposed for this application.
Heat-assisted magnetic recording is a nanophotonic approach to increasing the amount of data that a magnetic disk drive can store. It requires a laser to heat a tiny, subwavelength area of the magnetic material before writing data. The magnetic write-head would have metal optical components to concentrate light at the right location. Miniaturization in
optoelectronics, for example the miniaturization of transistors in
integrated circuits, has improved their speed and cost. However,
optoelectronic circuits can only be miniaturized if the optical components are shrunk along with the electronic components. This is relevant for on-chip
optical communication (i.e. passing information from one part of a microchip to another by sending light through optical waveguides, instead of changing the voltage on a wire).
Solar cells Solar cells often work best when the light is absorbed very close to the surface, both because electrons near the surface have a better chance of being collected, and because the device can be made thinner, which reduces cost. Researchers have investigated a variety of nanophotonic techniques to intensify light in the optimal locations within a solar cell.
Controlled release of anti-cancer therapeutics Nanophotonics has also been implicated in aiding the controlled and on-demand release of anti-cancer therapeutics like adriamycin from nanoporous optical antennas to target triple-negative breast cancer and mitigate exocytosis anti-cancer drug resistance mechanisms and therefore circumvent toxicity to normal systemic tissues and cells.
Spectroscopy Using nanophotonics to create high peak intensities: If a given amount of light energy is squeezed into a smaller and smaller volume ("hot-spot"), the intensity in the hot-spot gets larger and larger. This is especially helpful in
nonlinear optics; an example is
surface-enhanced Raman scattering. It also allows sensitive
spectroscopy measurements of even single molecules located in the hot-spot, unlike traditional spectroscopy methods which take an average over millions or billions of molecules.
Microscopy One goal of nanophotonics is to construct a so-called "
superlens", which would use
metamaterials (see below) or other techniques to create images that are more accurate than the diffraction limit (deep
subwavelength). In 1995, John M. Guerra demonstrated this by imaging a silicon grating having 50 nm lines and spaces with illumination having 650 nm wavelength in air. This was accomplished by coupling a transparent phase grating having 50 nm lines and spaces (metamaterial) with an immersion microscope objective (superlens).
Near-field scanning optical microscope (NSOM or SNOM) is a quite different nanophotonic technique that accomplishes the same goal of taking images with resolution far smaller than the wavelength. It involves raster-scanning a very sharp tip or very small aperture over the surface to be imaged. In another example,
dual-polarization interferometry has picometer resolution in the vertical plane above the waveguide surface.
Optical data storage Nanophotonics in the form of subwavelength near-field optical structures, either separate from the recording media, or integrated into the recording media, were first used by John M. Guerra and his team to achieve optical recording densities much higher than the diffraction limit allows. This work began in the 1980s at Polaroid Optical Engineering (Cambridge, Massachusetts), and continued under license at Calimetrics (Bedford, Massachusetts) with support from the NIST Advanced Technology Program.
Band-gap engineering In 2002, John M. Guerra (Nanoptek Corporation) demonstrated that nano-optical structures of semiconductors exhibit bandgap shifts because of induced strain. In the case of titanium dioxide, structures on the order of less than 200 nm half-height width will absorb not only in the normal ultraviolet part of the solar spectrum, but well into the high-energy visible blue as well. In 2008, Thulin and Guerra published modeling that showed not only bandgap shift, but also band-edge shift, and higher hole mobility for lower charge recombination. The band-gap engineered titanium dioxide is used as a photoanode in efficient photolytic and photo-electro-chemical production of hydrogen fuel from sunlight and water.
Silicon nanophotonics Silicon photonics is a
silicon-based subfield of nanophotonics in which nano-scale structures of the optoelectronic devices realized on silicon substrates and that are capable to control both light and electrons. They allow to couple electronic and optical functionality in one single device. Such devices find a wide variety of applications outside of academic settings, e.g. mid-infrared and
overtone spectroscopy, logic gates and cryptography on a chip etc. ==Principles==