<div dir="ltr"><div><div>I have not read the <i>Science</i> article below yet. However, the theme is important to us when placed in the photonic realm. In the electron realm mentioned here, it can lead to x-ray lasers (a patent I never wrote) and to sonoluminescence and sonofusion (papers I never completed). In the photonic realm, it leads to the ability to measure standing waves in a unique structure (overlays of photons in the same direction rather than in opposing directions) and to the concept of confining light to form photons. In the nuclear realm, it leads to virtual particle concepts and, perhaps, even the strong force.<br><br></div>It is a highly underutilized concept with both immense practical and theoretical applications.<br><br></div>Andrew<br><div><div><div><br><h1 id="compilation-3-1-article-title-1">A circular route to confine electrons</h1>
<div class=""><span class=""><a class="" href="http://www.sciencemag.org/search?author1=Ian+S.+Osborne&sortspec=date&submit=Submit">Ian S. Osborne</a></span><br>
</div>
<p id="compilation-3-1-p-2">Physical barriers
are used to confine waves. Whether it is harbor walls for sea waves, a
glass disk for light, or the “whispering
gallery” circular chamber walls in St.
Paul's Cathedral for sound, the principle of confinement—reflection—is
the same. Zhao
<em>et al.</em> used that same principle
to confine electrons in a nanoscale circular cavity in graphene.
Periodic patterns within the cavity
were associated with an electronic wave
version of whispering gallery modes. The tunability of the cavity size
may provide
a route for the manipulation of electrons
in graphene and similar materials.
</p>
<p id="compilation-3-1-p-3"><em>Science</em>, this issue p. <a href="http://www.sciencemag.org/lookup/doi/10.1126/science.aaa7469">672</a></p><br></div></div></div></div>