Laser / en ‘Flying saucer’ quantum dots hold secret to brighter, better lasers, say 鶹Ƶ researchers /news/flying-saucer-quantum-dots-hold-secret-brighter-better-lasers-say-u-t-researchers <span class="field field--name-title field--type-string field--label-hidden">‘Flying saucer’ quantum dots hold secret to brighter, better lasers, say 鶹Ƶ researchers</span> <div class="field field--name-field-featured-picture field--type-image field--label-hidden field__item"> <img loading="eager" srcset="/sites/default/files/styles/news_banner_370/public/2017-03-20-laser-sargent.jpg?h=afdc3185&amp;itok=z8qmxeYd 370w, /sites/default/files/styles/news_banner_740/public/2017-03-20-laser-sargent.jpg?h=afdc3185&amp;itok=mULvx-g9 740w, /sites/default/files/styles/news_banner_1110/public/2017-03-20-laser-sargent.jpg?h=afdc3185&amp;itok=G5xCjHbd 1110w" sizes="(min-width:1200px) 1110px, (max-width: 1199px) 80vw, (max-width: 767px) 90vw, (max-width: 575px) 95vw" width="740" height="494" src="/sites/default/files/styles/news_banner_370/public/2017-03-20-laser-sargent.jpg?h=afdc3185&amp;itok=z8qmxeYd" alt="sargent researchers"> </div> <span class="field field--name-uid field--type-entity-reference field--label-hidden"><span>ullahnor</span></span> <span class="field field--name-created field--type-created field--label-hidden"><time datetime="2017-03-20T10:46:35-04:00" title="Monday, March 20, 2017 - 10:46" class="datetime">Mon, 03/20/2017 - 10:46</time> </span> <div class="clearfix text-formatted field field--name-field-cutline-long field--type-text-long field--label-above"> <div class="field__label">Cutline</div> <div class="field__item">Researcher Fengjia Fan shows off a vial of colloidal quantum dots that glow red when excited by UV light. Randy Sabatini, Alex Voznyy and Kris Bicanic are using the quantum dots to develop brighter lasers that use less energy (photo by Kevin Soobrian)</div> </div> <div class="field field--name-field-author-reporters field--type-entity-reference field--label-hidden field__items"> <div class="field__item"><a href="/news/authors-reporters/tyler-irving" hreflang="en">Tyler Irving</a></div> </div> <div class="field field--name-field-author-legacy field--type-string field--label-above"> <div class="field__label">Author legacy</div> <div class="field__item">Tyler Irving</div> </div> <div class="field field--name-field-topic field--type-entity-reference field--label-above"> <div class="field__label">Topic</div> <div class="field__item"><a href="/news/topics/breaking-research" hreflang="en">Breaking Research</a></div> </div> <div class="field field--name-field-story-tags field--type-entity-reference field--label-hidden field__items"> <div class="field__item"><a href="/news/tags/quantum" hreflang="en">Quantum</a></div> <div class="field__item"><a href="/news/tags/ted-sargent" hreflang="en">Ted Sargent</a></div> <div class="field__item"><a href="/news/tags/laser" hreflang="en">Laser</a></div> </div> <div class="field field--name-field-subheadline field--type-string-long field--label-above"> <div class="field__label">Subheadline</div> <div class="field__item">Research team led by 鶹Ƶ's Faculty of Applied Science &amp; Engineering ‘squashes’ the shape of nanoparticles, enabling inexpensive lasers that emit light in a customized rainbow of colours</div> </div> <div class="clearfix text-formatted field field--name-body field--type-text-with-summary field--label-hidden field__item"><p>More accurate medical tests, vivid&nbsp;video projectors and fresh insights into living cells are just three of the innovations that could result from new lasers that use nanoparticles to create brighter&nbsp;light in a rainbow of colours.&nbsp;</p> <p>A new method, developed by an international research team from 鶹Ƶ's Faculty of Applied Science &amp; Engineering, Vanderbilt University, the Los Alamos National Laboratory and others&nbsp;produces continuous laser light that is less expensive, brighter and more customized than current devices by using nanoparticles known as quantum dots.</p> <p>“We’ve been working with quantum dots for more than a decade,” says <strong>Ted Sargent</strong>, a professor in the department of electrical and&nbsp;computer engineering at 鶹Ƶ. “They are more than five thousand times smaller than the width of a human hair, which enables them to straddle the worlds of quantum and classical physics and gives them useful optical properties.”</p> <p>“Quantum dots are well-known bright light emitters,” says <strong>Alex Voznyy</strong>, a senior research associate in Sargent’s lab. “They can absorb a lot of energy and re-emit it at a particular frequency, which makes them a particularly suitable material for lasers.”</p> <p><img alt class="media-image attr__typeof__foaf:Image img__fid__3870 img__view_mode__media_original attr__format__media_original" src="/sites/default/files/QuantumDots-embed.jpg" style="width: 750px; height: 500px;" typeof="foaf:Image"><br> <em>This solution of quantum dots glows bright red when in absorbs light from a UV lamp underneath. Researchers from 鶹Ƶ Engineering are optimizing these nanoparticles to create brighter lasers that use less energy than current models&nbsp;(photo by&nbsp;Kevin Soobrian)</em></p> <p>By carefully controlling the size of the quantum dots, the researchers in Sargent’s lab can ‘tune’ the frequency&nbsp;or colour&nbsp;of the emitted light to any desired value. By contrast, most commercial lasers are limited to one specific frequency, or a very small range, defined by the materials they are made from.</p> <p>The ability to produce a laser of any desired frequency from a single material would give a boost to scientists looking to study diseases at the level of tissues or individual cells by offering new tools to probe biochemical reactions. They could also enable laser display projectors that would be brighter and more energy efficient than current LCD technology.</p> <p>But although the ability of colloidal quantum dots to produce laser light was first demonstrated by co-author Victor Klimov and his team at Los Alamos National Laboratory more than 15 years ago, commercial application has remained elusive. A key problem has been that until now, the amount of light needed to excite the quantum dots to produce laser light has been very high.&nbsp;</p> <p>“You have to stimulate the laser using more and more power, but there are a lot of heating losses as well,” says Voznyy. “Eventually, it gets so hot that it just burns.”</p> <p>Most quantum dot lasers are limited to pulses of light lasting just a few nanoseconds –&nbsp;billionths of a second.</p> <p>The team, which included Voznyy, postdoctoral researchers <strong>Fengjia Fan</strong> and <strong>Randy Sabatini</strong> and master's student&nbsp;<strong>Kris Bicanic</strong>, overcame this problem by changing the shape of the quantum dots, rather than their size. They were able to create quantum dots with a spherical core and a shell shaped like a Skittle, an M&amp;M or a flying saucer –&nbsp;a ‘squashed’ spherical shape known as an oblate spheroid.</p> <p>The mismatch between the shape of the core and the shell introduces a tension that affects the electronic states of the quantum dot, lowering the amount of energy needed to trigger the laser. As reported in a paper published today in <em><a href="http://www.nature.com/nature/journal/vaop/ncurrent/full/nature21424.html">Nature</a></em>, the innovation means that the quantum dots are no longer in danger of overheating, so the resulting laser can fire continuously.</p> <p><img alt class="media-image attr__typeof__foaf:Image img__fid__3871 img__view_mode__media_original attr__format__media_original" src="/sites/default/files/quantum-embed.jpg" style="width: 750px; height: 569px;" typeof="foaf:Image"><br> <em>This computer-generated model shows the spherical core of the quantum dot nanoparticle (in red) along with the ‘flying saucer’ shape of the outer shell (in yellow). The tension in the core induced by the shell affects the electronic states and lowers the energy threshold required to trigger the laser&nbsp;(image by&nbsp;Alex Voznyy) &nbsp;</em></p> <p>While quantum dots are often built by depositing molecules one at a time in a vacuum, Sargent’s team mixes together liquid solutions that contain various quantum dot precursors. When the solutions react, they produce solid quantum dots that stay suspended in the liquid –&nbsp;these are known as colloidal quantum dots. The team’s key innovation was to add specific capping molecules into the mix, which allowed them to control the shape of the particles to obtain the desired properties, an approach Fan calls ‘smart chemistry.’</p> <p>“Solution-based processing greatly reduces the cost of making quantum dots,” says Fan. “It will also make it easier to scale up production&nbsp;because we can use techniques already established in the printing industry.”</p> <p>The project included a number of national and international partners. Computer simulations in collaboration with the University of Ottawa and the National Research Council guided the design of the quantum dots. Analytical tests from Vanderbilt’s Institute of Nanoscale Science and Engineering in Nashville, TN, as well as the University of New Mexico’s Center for High Technology Materials in Albuquerque, NM and Los Alamos confirmed that the final products had the desired shape, composition and behaviour by analyzing individual quantum dots at the atomic level.</p> <p>“We were impressed not only by the engineered structure itself but also by the level of uniformity they have achieved,” says Sandra Rosenthal, director of the Vanderbilt Institute for Nanoscale Science and Engineering. “Sargent’s team has managed to create quantum dots with a unique and elegant structure. This is exciting research.”</p> <p>The team has more work to do before they can look to commercialization.</p> <p>“For this proof-of-concept device, we’re exciting the quantum dots with light,” says Sabatini. “Ultimately, we want to move to exciting them with electricity. We also want to scale up the power to milliwatts or even watts. If we can do that, then it becomes important for laser projection.”</p> </div> <div class="field field--name-field-news-home-page-banner field--type-boolean field--label-above"> <div class="field__label">News home page banner</div> <div class="field__item">Off</div> </div> Mon, 20 Mar 2017 14:46:35 +0000 ullahnor 105995 at