...

   The speed of light in gases is slightly slower:  It is about 0.05%
   lower in air at sea level.
   The speed of light in typical glass is about 2/3's of 'c'.
   In typical glass, the speed of light varies a bit with wavelength.
   [1]https://en.wikipedia.org/wiki/Prism
   For many decades, diffraction gratings have been used to separate
   colors of light.
   [2]https://en.wikipedia.org/wiki/Diffraction_grating
   The shiny surface of a CDROM or DVD approximates that of a diffraction
   grating,
   You can aim the beam from a laser at a CDROM or DVD to see different
   reflections.
   If you start with a light beam generated with a LED (Light Emitting
   Diode; which has a much wider spectrum than a laser) you could see the
   spectrum it possesses.

   another fun feature of light interaction is that it can induce matter
   into cohesive movements, like vortices:

   [3]https://phys.org/news/2019-05-whirlpools-electrons.html

                        Twisting whirlpools of electrons

   by [4]Ecole Polytechnique Federale de Lausanne

   In Jules Verne's famous classic 20,000 Leagues Under the Sea, the
   iconic submarine Nautilus disappears into the Moskenstraumen, a massive
   whirlpool off the coast of Norway. In space, stars spiral around black
   holes; on Earth, swirling cyclones, tornadoes and dust devils rip
   across the land.

   All these phenomena have a vortex shape, which is commonly found in
   nature, from galaxies to milk stirred into coffee. In the subatomic
   world, a stream of elementary particles or energy will spiral around a
   fixed axis like the tip of a corkscrew. When particles move like this,
   they form what we call "[5]vortex beams." These beams imply that the
   particle has a well-defined orbital angular momentum, which describes
   the rotation of a particle around a fixed point.

   Thus, vortex beams can give us new ways of interacting with matter,
   e.g. enhanced sensitivity to magnetic fields in sensors, or generating
   new absorption channels for the interaction between radiation and
   tissue in medical treatments (e.g. radiotherapy). But vortex beams also
   enable new channels in basic interactions among elementary particles,
   promising new insights into the inner structure of particles such as
   neutrons, protons or ions.

   Matter exhibits wave-particle duality. This means that scientists can
   make massive particles form vortex beams simply by modulating their
   wave function. This can be done with a device called a "passive phase
   mask," which can be thought of as a standing obstacle in the sea. When
   waves at sea crash into it, their "wave-ness" shifts and they form
   whirlpools. Physicists have been using the passive phase mask method to
   make vortex beams of electrons and neutrons.

   But now, scientists from the lab of Fabrizio Carbone at EPFL have
   demonstrated that it is possible to use light to dynamically twist an
   individual electron's wave function. They were able to generate an
   ultrashort vortex electron beam and actively switch its vorticity on
   the attosecond (10^-18 seconds) timescale.

   To do this, the team exploited one of the fundamental rules governing
   the interaction of particles on the nanoscale level: energy and
   momentum conservation. What this means is that the sum of the energies,
   masses and velocities of two particles before and after their collision
   must be the same. This constraint causes an electron to gain orbital
   angular momentum during its interaction with an ad hoc prepared light
   field, i.e. a chiral plasmon.

   In experimental terms, the scientists fired circularly polarized,
   ultrashort laser pulses through a nano-hole in a metallic film. This
   induced a strong, localized electromagnetic field (the chiral plasmon),
   and individual electrons were made to interact with it. The scientists
   used an ultrafast transmission electron microscope to monitor the
   resulting phase profiles of the electrons. What they discovered was
   that during the interaction of the electrons with the field, the
   [6]wave function of the electrons took on a chiral modulation, a right-
   or left-handed movement whose "handedness" can be actively controlled
   by adjusting the polarization of the laser pulses.

   "There are many practical applications from these experiments," says
   Fabrizio Carbone. "Ultrafast [7]vortex electron beams can be used to
   encode and manipulate quantum information; the electrons' orbital
   [8]angular momentum can be transferred to the spins of magnetic
   materials to control the topological charge in new devices for data
   storage. But even more intriguingly, using light to dynamically twist
   matter waves offers a new perspective in shaping protons or ion beams
   such as those used in medical therapy, possibly enabling new
   radiation-matter interaction mechanisms that can be very useful for
   selective tissue ablation techniques."

   More information: G. M. Vanacore, et al. Ultrafast generation and
   control of an electron vortex beam via chiral plasmonic near fields.
   Nature Materials 06 May 2019.

   [9]http://dx.doi.org/10.1038/s41563-019-0336-1

References

   1. https://en.wikipedia.org/wiki/Prism
   2. https://en.wikipedia.org/wiki/Diffraction_grating
   3. https://phys.org/news/2019-05-whirlpools-electrons.html
   4. http://www.epfl.ch/
   5. https://phys.org/tags/vortex+beams/
   6. https://phys.org/tags/wave+function/
   7. https://phys.org/tags/vortex/
   8. https://phys.org/tags/angular+momentum/
   9. http://dx.doi.org/10.1038/s41563-019-0336-1