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Researchers succeed in an 80-year-old quest to find the elusive "angel particle".
24 July, 2017
A composite view of the Crab nebula viewed by the Herschel Space Observatory and the Hubble Space Telescope (Image: NASA)
A team of scientists found first evidence for the existence of a Majorana fermion, a hypothetical particle proposed 80 years ago that is its own antiparticle.
<p>In 1928, physicist <strong>Paul Dirac</strong> predicted that every fundamental particle has an antiparticle - a twin that has an opposite charge. If a particle and antiparticle were to meet, they would be annihilated while releasing a burst of energy. But in 1937, physicist <strong>Ettore Majorana</strong> added the prediction that a class of particles exists known as <strong>fermions</strong>, which would include particles that are their own antiparticles.</p> <p>Now the researchers from Stanford University and University of California found the Majorana fermion in a series of lab experiments on exotic materials. They were led by UC-Irvine Associate Professor <strong>Jing Xia</strong> and UCLA Professor <strong>Kang Wang,</strong> and followed a plan proposed by the Stanford physics professor<strong> </strong><a href="https://profiles.stanford.edu/shoucheng-zhang" target="_blank"><strong>Shoucheng Zhang</strong></a><strong>.</strong></p> <p>Professor Zhang, one of the senior authors of the paper, put their finding in perspective:</p> <blockquote><p>“Our team predicted exactly where to find the Majorana fermion and what to look for as its ‘smoking gun’ experimental signature,” <a href="http://news.stanford.edu/2017/07/20/evidence-particle-antiparticle/" target="_blank"><span>said Zhang.</span></a> “This discovery concludes one of the most intensive searches in fundamental physics, which spanned exactly 80 years.”</p></blockquote> <p>Want to learn more about antimatter? Let Michio Kaku explain:</p> <div class="video-full-card-placeholder" data-slug="the-search-for-antimatter-2" style="border: 1px solid #ccc;"> <div class="rm-shortcode" data-media_id="I67qqHc0" data-player_id="FvQKszTI" data-rm-shortcode-id="4dbc73ab0d57d9bce55c5008ccf14027"> <div id="botr_I67qqHc0_FvQKszTI_div" class="jwplayer-media" data-jwplayer-video-src="https://content.jwplatform.com/players/I67qqHc0-FvQKszTI.js"> <img src="https://cdn.jwplayer.com/thumbs/I67qqHc0-1920.jpg" class="jwplayer-media-preview"> </div> <script src="https://content.jwplatform.com/players/I67qqHc0-FvQKszTI.js"></script> </div> </div> <p>The complexity of the experiments necessary to find the Majorana fermion makes this work a “landmark in the field,” <a href="http://news.stanford.edu/2017/07/20/evidence-particle-antiparticle/" target="_blank"><span>said Tom Devereaux,</span></a> director of the Stanford Institute for Materials and Energy Sciences.</p> <p>Nobel Prize-winning theoretical physicist <strong>Frank Wilczek,</strong> who was not involved in the research, <a href="http://news.stanford.edu/2017/07/20/evidence-particle-antiparticle/" target="_blank"><span>also praised</span></a> the importance of the discovery, calling it “a really clean observation of something new” and a “real milestone”.</p> <p>The fermion observed by the team is known as a <strong>“chiral”</strong> fermion as it moves in just one direction along a one-dimensional path. </p> <p>The experiment that resulted in the find involved looking for a special half-speed signature of Majorana <strong><em>quasiparticles</em></strong>, which are “excitations” that come from how electrons behave in superconducting materials. While these are special entities that have some properties of particles but are not actually particles found in nature, <em>quasiparticles</em> are still regarded as real Majorana fermions. </p> <p>The researchers applied electricity to stacks of superconducting materials and topological insulators in a chilled chamber. A topological insulator conducts current along its surface or edges only, not through the middle. A magnet was then used to control the behavior of generated electrons as they sped along the edges of the surface. The electrons were slowed down, stopped and their direction changed. This cycle continued until the scientists identified the Majorana quasiparticles that emerged by by their unique speeds. </p> <p>The practical implications of this discovery are well in the future, with potential for use in quantum computing, where it can help overcome environmental noise. <a href="http://news.stanford.edu/2017/07/20/evidence-particle-antiparticle/" target="_blank"><span>Zhang calls</span></a> the newly-found particle the <strong>“angel particle,”</strong> referring to Dan Brown’s bestseller “Angels and Demons” which featured a matter/anti-matter time bomb as part of the plot.</p> <p><a href="http://science.sciencemag.org/content/357/6348/252" target="_blank">Read the study here, in <em>Science </em>magazine.</a></p> <p>You can watch Professor Zhang discuss the search and discovery of the Majorana Fermion here:</p> <div><span style="display:block;position:relative;padding-top:56.25%;" class="rm-shortcode" data-rm-shortcode-id="7c2fe60946f562b8f45aadbda3754161"><iframe type="lazy-iframe" data-runner-src="https://www.youtube.com/embed/sbJSAOngiGI?rel=0" width="100%" height="auto" frameborder="0" scrolling="no" style="position:absolute;top:0;left:0;width:100%;height:100%;"></iframe></span></div>
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physics quantum big bang science angel particle Dan Brown Angels and Demons Shoucheng Zhang Frank Wilczek technology weird science