{"id":935,"date":"2019-11-13T19:15:33","date_gmt":"2019-11-13T19:15:33","guid":{"rendered":"https:\/\/magazine.mcs.cmu.edu\/physics\/?page_id=935"},"modified":"2019-11-21T18:07:09","modified_gmt":"2019-11-21T18:07:09","slug":"research-notes","status":"publish","type":"page","link":"https:\/\/magazine.mcs.cmu.edu\/physics\/issue-2019\/research-notes\/","title":{"rendered":"Research Notes"},"content":{"rendered":"<p>[et_pb_section fb_built=&#8221;1&#8243; fullwidth=&#8221;on&#8221; _builder_version=&#8221;3.14&#8243; custom_margin=&#8221;|||&#8221;][et_pb_fullwidth_image src=&#8221;https:\/\/magazine.mcs.cmu.edu\/physics\/wp-content\/uploads\/sites\/4\/2019\/11\/rothstein_russ_cover.jpg&#8221; _builder_version=&#8221;3.14&#8243;][\/et_pb_fullwidth_image][\/et_pb_section][et_pb_section fb_built=&#8221;1&#8243; _builder_version=&#8221;3.14&#8243; background_color=&#8221;#2b2b2b&#8221; custom_margin=&#8221;|||&#8221; custom_padding=&#8221;0|0px|0|0px|false|false&#8221;][et_pb_row custom_padding=&#8221;0|0px|0|0px|false|false&#8221; _builder_version=&#8221;3.14&#8243;][et_pb_column type=&#8221;4_4&#8243; _builder_version=&#8221;3.14&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_image src=&#8221;https:\/\/magazine.mcs.cmu.edu\/physics\/wp-content\/uploads\/sites\/4\/2019\/11\/Research-Notes.png&#8221; align=&#8221;right&#8221; _builder_version=&#8221;3.14&#8243;][\/et_pb_image][\/et_pb_column][\/et_pb_row][et_pb_row custom_padding=&#8221;0|0px|29px|0px|false|false&#8221; custom_margin=&#8221;|||&#8221; _builder_version=&#8221;3.14&#8243;][et_pb_column type=&#8221;4_4&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_text _builder_version=&#8221;3.14&#8243; text_font=&#8221;||||||||&#8221; header_font=&#8221;|600||on|||||&#8221; header_text_color=&#8221;#9dd0fb&#8221; header_font_size=&#8221;51px&#8221; custom_margin=&#8221;|||&#8221;]<\/p>\n<h1>THE THEORY BEHIND THE EXPERIMENT<\/h1>\n<p>[\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row custom_padding=&#8221;0|0|0|0px|false|false&#8221; custom_margin=&#8221;|||&#8221; padding_top_1=&#8221;0px&#8221; _builder_version=&#8221;3.14&#8243; border_width_all=&#8221;10px&#8221; border_color_all=&#8221;rgba(0,0,0,0)&#8221;][et_pb_column type=&#8221;1_3&#8243; _builder_version=&#8221;3.0.47&#8243; padding_top=&#8221;0px&#8221; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_text _builder_version=&#8221;3.14&#8243; text_font=&#8221;||||||||&#8221; text_text_color=&#8221;#ffffff&#8221; inline_fonts=&#8221;Times New Roman&#8221;]<\/p>\n<p><span class=\"et-dropcap\" style=\"color: #9dd0fb;\">I<\/span>n December 1973, Professor James Russ was working the nightshift at Brookhaven National Lab. His experiment was going well, so he wandered over to the MIT trailer to see what the researchers there were working on. Russ noticed a striking image on the wall. When he asked the researchers in the lab what it was, they said \u201cwe\u2019re not allowed to talk about it.\u201d<\/p>\n<p>The MIT researchers were working with Samuel C.C. Ting, and that picture was part of the data that lead to the first discovery in high-energy proton interactions of the j\/psi meson, the subatomic particle made up of a charm quark and charm antiquark that would spark physics\u2019 November Revolution and earn Ting and Stanford\u2019s Burton Richter the 1976 Nobel Prize in physics.<\/p>\n<p>Little did Russ know that j\/psi would figure prominently in his research for the next 45 years.<\/p>\n<p>The discovery of j\/psi was monumental, but the task of explaining theoretically how the particle is produced proved to be an even bigger feat.<\/p>\n<blockquote style=\"color: #9dd0fb;\">\n<p><span style=\"font-size: x-large;\"><em><strong><span style=\"font-family: Times New Roman;\">\u201cThis is the story about how j\/psi is made.\u201d &#8211; Russ<\/span><\/strong><\/em><\/span><\/p>\n<\/blockquote>\n<p>The most popular early theory posited that the j\/psi was a state of extra-heavy particles called charm quarks bound together by the strong interaction, much like the electron and proton are bound together by electromagnetic force in an atom.<\/p>\n<p>\u201cThere was a prediction made in the mid-90s that when j\/psi are produced they are polarized, meaning that they should be spinning in a very particular way. But the initial data did not seem to agree with this prediction. This was a very serious challenge to a theory that was, for all intents and purposes, accepted by the physics community,\u201d said Professor Ira Rothstein. \u201cThere was still hope that the data was incomplete or wrong, but there was considerable handwringing in the theoretical community.\u201d<\/p>\n<p>[\/et_pb_text][\/et_pb_column][et_pb_column type=&#8221;1_3&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_text _builder_version=&#8221;3.14&#8243; text_font=&#8221;||||||||&#8221; text_text_color=&#8221;#ffffff&#8221; inline_fonts=&#8221;Times New Roman&#8221;]<\/p>\n<p>Two decades after j\/psi\u2019s discovery, Russ and his colleagues working on the Collider Detector at Fermilab experiments finally proved that the prevailing theory was inadequate.<\/p>\n<p>\u201cWhen we measured how often the j\/psi particles were produced we found that the theoretical prediction was off by a factor of 10,\u201d said Russ. Then, in a later study, Russ and his students found that the j\/psi particles were not polarized as the theory predicted.<\/p>\n<p>It was then that the theorist Rothstein stepped in. Rothstein and his postdoc at the time Matthew Baumgart, along with the University of Pittsburgh\u2019s Adam Leibovich and Duke University\u2019s Tom Mehen, set out to come up with an explanation for why the theory wasn\u2019t matching the data. The group of theorists postulated that perhaps the lack of polarization was due to a large enhancement from production that washed out the polarization. They also predicted that if this postulate were true, there would be a unique signal elsewhere in the data.<\/p>\n<p style=\"text-align: right;\">\u00a0<\/p>\n<p>[\/et_pb_text][et_pb_slider show_image_video_mobile=&#8221;on&#8221; _builder_version=&#8221;3.14&#8243; background_color=&#8221;#9dd0fb&#8221;][et_pb_slide heading=&#8221;Theory Meets Data&#8221; image=&#8221;https:\/\/magazine.mcs.cmu.edu\/physics\/wp-content\/uploads\/sites\/4\/2019\/11\/rothstein_russ_1.jpg&#8221; _builder_version=&#8221;3.14&#8243; background_layout=&#8221;light&#8221;]A plot of Russ\u2019 measurements compared to Rothstein\u2019s predictions of the four possible theoretical outcomes. One of the four predictions matches the data exactly, showing that the theory is correct and identifying the specific way that the two heavy quarks combine to make the j\/psi fragment.[\/et_pb_slide][\/et_pb_slider][\/et_pb_column][et_pb_column type=&#8221;1_3&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_text _builder_version=&#8221;3.14&#8243; text_font=&#8221;||||||||&#8221; text_text_color=&#8221;#ffffff&#8221;]When you see an image of a high-energy collision, it\u2019s like a star burst, with streams coming from the center, ending in a particle. Those streams, called jets, are clusters of particles breaking apart as they travel from the collision\u2019s center. Rothstein and his collaborators calculated the creation rate for the j\/psi particle in these jets and found the unique signal from their postulate.<\/p>\n<p>\u201cWe knew that the experimental analysis needed to test our prediction would be very challenging. We thought it would take a team of scientists to do the job,\u201d said Rothstein. \u201cBut we underestimated Jim\u2019s stamina and determination. He is a real scientific bulldog. Once he sinks his teeth into a problem he doesn\u2019t let it go until he\u2019s completely dissected it.\u201d<\/p>\n<p>Russ took data from his project at the Large Hadron Collider\u2019s Compact Muon Solenoid experiment, which looked at jets formed by the collider\u2019s high-energy collisions. He combined his jet data with data from groups studying j\/psi particle production. This was the first time in history that the two types of data have ever been combined.<\/p>\n<p>\u201cThis is the first time we\u2019ve taken apart a jet to ask and answer questions,\u201d said Russ. \u201cYou could pick apart the jet and the heavy particles, look at their angular correlations and test the theory.\u201d<\/p>\n<p>From the accumulated data, Russ confirmed the prediction based on modified theory. His results mark exciting milestones in both experimental and theoretical work and demonstrate the groundbreaking collaborations between theorists and experimentalists at Carnegie Mellon.<\/p>\n<p style=\"text-align: right;\"><em>\u25a0\u00a0Jocelyn Duffy<\/em><\/p>\n<p>[\/et_pb_text][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=&#8221;1&#8243; _builder_version=&#8221;3.14&#8243; custom_padding=&#8221;0|0px|0|0px|false|false&#8221;][et_pb_row custom_padding=&#8221;30px|0px|0|0px|false|false&#8221; _builder_version=&#8221;3.14&#8243;][et_pb_column type=&#8221;4_4&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_text _builder_version=&#8221;3.14&#8243; header_font=&#8221;|||on|||||&#8221; header_font_size=&#8221;55px&#8221; header_3_font=&#8221;||||||||&#8221; header_3_font_size=&#8221;38px&#8221;]<\/p>\n<h1><strong>Research<\/strong> Notes<\/h1>\n<p>[\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row custom_padding=&#8221;0|0px|0|0px|false|false&#8221; custom_margin=&#8221;30px||30px||true&#8221; _builder_version=&#8221;3.14&#8243; border_width_left=&#8221;10px&#8221; border_color_left=&#8221;#bb0000&#8243;][et_pb_column type=&#8221;3_5&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_text _builder_version=&#8221;3.14&#8243; text_font=&#8221;||||||||&#8221; header_font=&#8221;||||||||&#8221; header_text_color=&#8221;#e02b20&#8243; header_2_font=&#8221;|700||on|||||&#8221; header_2_text_color=&#8221;#bb0000&#8243; custom_margin=&#8221;|||&#8221; custom_padding=&#8221;|||10px&#8221;]<\/p>\n<h2>SuperKEKB Starts Physics Run<\/h2>\n<p>The Phase 3 operation of SuperKEKB, an electron-positron collider at the High Energy Accelerator Research Organization in Japan, began in mid-March in preparation for the beginning of the project\u2019s physics run. Just two weeks later, the project recorded the first data from electron-positron collisions with the Belle II detector.<\/p>\n<p>Professor Roy Briere is a member of the Belle II collaboration, which seeks to find new physics hidden in subatomic particles, and leads Carnegie Mellon\u2019s participation in the project. Jake Bennett, now an assistant professor at the University of Mississippi, worked on the project as a postdoc in Briere\u2019s group. Jitendra Kumar, a current postdoc in Briere\u2019s group, is calibrating the ionization measurements of charge particles, which will allow the detector to distinguish between several possible particle types. Graduate student Emma Oxford is helping to improve simulations of charm particle decays and preparing to use the Belle II data to search for CP violation in a particular charm meson decay. Alumnus Nick Hougland, who worked with Briere as an undergraduate, performed detailed studies of charm meson decays for a simulation that will be used to update the detector to better match the particles\u2019 known behaviors.<\/p>\n<p>Briere will host the 14th International Conference on Beauty, Charm and Hyperons (BEACH2020), which focuses on physics related to Belle II and beyond, in Pittsburgh this spring.[\/et_pb_text][\/et_pb_column][et_pb_column type=&#8221;2_5&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_gallery gallery_ids=&#8221;953,954,955&#8243; fullwidth=&#8221;on&#8221; hover_icon=&#8221;%%33%%&#8221; _builder_version=&#8221;3.14&#8243; title_font=&#8221;||||||||&#8221; caption_text_align=&#8221;left&#8221; caption_text_shadow_style=&#8221;preset1&#8243; caption_text_shadow_blur_strength=&#8221;0.46em&#8221; caption_text_shadow_color=&#8221;#ffffff&#8221; pagination_font=&#8221;||||||||&#8221; pagination_text_color=&#8221;#ffffff&#8221; custom_padding=&#8221;5px|10px|5px|10px|true|true&#8221; auto=&#8221;on&#8221; auto_speed=&#8221;3000&#8243; custom_css_gallery_item_caption=&#8221;width: 100%!important;||padding: 380px 0 30px 0!important;||text-align: left;||animation-duration: 0s!important;||animation-delay: 0s!important; &#8220;][\/et_pb_gallery][\/et_pb_column][\/et_pb_row][et_pb_row custom_padding=&#8221;0|0px|0|0px|false|false&#8221; custom_margin=&#8221;50px||50px||true&#8221; _builder_version=&#8221;3.14&#8243; border_width_right=&#8221;10px&#8221; border_color_right=&#8221;#0b2cbf&#8221;][et_pb_column type=&#8221;2_5&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_gallery gallery_ids=&#8221;956,957&#8243; fullwidth=&#8221;on&#8221; hover_icon=&#8221;%%2%%&#8221; _builder_version=&#8221;3.14&#8243; custom_padding=&#8221;5px|10px|5px|10px||true&#8221; auto=&#8221;on&#8221; auto_speed=&#8221;3000&#8243;][\/et_pb_gallery][\/et_pb_column][et_pb_column type=&#8221;3_5&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_text _builder_version=&#8221;3.14&#8243; header_font=&#8221;||||||||&#8221; header_text_color=&#8221;#e02b20&#8243; header_2_font=&#8221;|700||on|||||&#8221; header_2_text_color=&#8221;#0b2cbf&#8221; custom_padding=&#8221;|10px||&#8221;]<\/p>\n<h2>Simulation Demonstrates Dynamin-Driven Membrane Fission<\/h2>\n<p>A cell\u2019s lipid membrane is a fortress that separates its interior from its environment. It determines what molecules can enter the cell, such as molecules that regulate protein processing, energy production and the immune response. One way it does this is through dynamin-driven membrane fission. When this process doesn\u2019t work, it prevents the molecules from doing their jobs in the cell, which can lead to disease.<\/p>\n<p>Professor Markus Deserno, graduate student Zachary McDargh and former postdoctoral researcher Martina Pannuzzo created a computational model that simulates the geometry of the lipid membrane and dynamin and used this model to test theories about how dynamin-driven membrane fission works. They found that dynamin likely brings molecules into the cell by twirling its filament to create torques that help detach vesicles from the lipid membrane.<\/p>\n<p>\u201cOur findings offer a detailed biophysical assessment of how dynamin\u2019s geometry, elasticity, molecular interactions and expenditure of chemical energy work together to drive membrane fission \u2014 or how this might fail in several dynamin-related diseases,\u201d said Deserno.[\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row custom_padding=&#8221;1px|0px|0|0px|false|false&#8221; _builder_version=&#8221;3.14&#8243; border_width_left=&#8221;10px&#8221; border_color_left=&#8221;#009378&#8243;][et_pb_column type=&#8221;3_5&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_text _builder_version=&#8221;3.14&#8243; header_font=&#8221;||||||||&#8221; header_text_color=&#8221;#e02b20&#8243; header_2_font=&#8221;|700||on|||||&#8221; header_2_text_color=&#8221;#009378&#8243; border_width_left=&#8221;10px&#8221; border_color_left=&#8221;rgba(0,0,0,0)&#8221;]<\/p>\n<h2>Shedding Light on the Mass \u2028of Sound<\/h2>\n<p>Most of us normally think that sound travels through the air without shape or substance. A recent study building on research conducted by Assistant Professor Riccardo Penco has shown that sound waves actually have a small amount of mass that is in a possibly exotic form. The paper was published in the journal Physical Review Letters and featured in Scientific American.<\/p>\n<p>\u201cThis is something that started with a paper published when I was at the University of Pennsylvania,\u201d Penco said of his contribution to the research as a postdoctoral fellow before joining the faculty of Carnegie Mellon. That study, published in the journal Physical Review B, looked at the behavior of phonons, which are akin to particles of sound waves like photons are to particles of light waves, under quantum mechanics.[\/et_pb_text][\/et_pb_column][et_pb_column type=&#8221;2_5&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_gallery gallery_ids=&#8221;958&#8243; fullwidth=&#8221;on&#8221; hover_icon=&#8221;%%2%%&#8221; _builder_version=&#8221;3.14&#8243; caption_text_shadow_style=&#8221;preset1&#8243; caption_text_shadow_color=&#8221;#000000&#8243; pagination_font=&#8221;||||||||&#8221; custom_padding=&#8221;5px|10px|5px|10px||true&#8221; auto=&#8221;on&#8221; auto_speed=&#8221;3000&#8243;][\/et_pb_gallery][\/et_pb_column][\/et_pb_row][et_pb_row custom_padding=&#8221;0|0px|3px|0px|false|false&#8221; custom_margin=&#8221;50px||50px||true&#8221; _builder_version=&#8221;3.14&#8243; border_width_right=&#8221;10px&#8221; border_color_right=&#8221;#0c71c3&#8243;][et_pb_column type=&#8221;2_5&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_gallery gallery_ids=&#8221;964,963&#8243; fullwidth=&#8221;on&#8221; hover_icon=&#8221;%%2%%&#8221; _builder_version=&#8221;3.14&#8243; custom_padding=&#8221;5px|10px|5px|10px||true&#8221; auto=&#8221;on&#8221; auto_speed=&#8221;3000&#8243;][\/et_pb_gallery][\/et_pb_column][et_pb_column type=&#8221;3_5&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_text _builder_version=&#8221;3.14&#8243; header_font=&#8221;||||||||&#8221; header_text_color=&#8221;#e02b20&#8243; header_2_font=&#8221;|700||on|||||&#8221; header_2_text_color=&#8221;#0c71c3&#8243; border_width_right=&#8221;10px&#8221; border_color_right=&#8221;rgba(0,0,0,0)&#8221;]<\/p>\n<h2>Dark Matter on the Move<\/h2>\n<p>While hunting for evidence of dark matter at the centers of dwarf galaxies, Assistant Professor Matthew Walker, with his colleagues from the University of Surrey and ETH-Z\u00fcrich, found the first evidence for dark matter heating.<\/p>\n<p>When stars form, strong winds push gas and dust away from the center of a galaxy. As a result, the galaxy\u2019s center has less mass, affecting how much gravity is felt by the remaining dark matter. With less gravitational attraction, the dark matter gains energy and migrates away from the center, an effect called dark matter heating.<\/p>\n<p>The team measured the amount of dark matter at the center of 16 dwarf galaxies and found that the galaxies that stopped forming stars long ago had higher dark matter densities at their centers than those that were still forming stars, supporting the theory that older galaxies have less dark matter heating.<\/p>\n<p>\u201cThis study may be the \u2018smoking gun\u2019 evidence that takes us a step closer to understanding what dark matter is. Our finding that it can be heated up and moved around helps to motivate searches for a dark matter particle,\u201d said Walker.[\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row custom_padding=&#8221;0|0px|0|0px|false|false&#8221; custom_margin=&#8221;30px||30px||true&#8221; _builder_version=&#8221;3.14&#8243; border_width_left=&#8221;10px&#8221; border_color_left=&#8221;#b59f41&#8243;][et_pb_column type=&#8221;3_5&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_text _builder_version=&#8221;3.14&#8243; header_font=&#8221;||||||||&#8221; header_text_color=&#8221;#e02b20&#8243; header_2_font=&#8221;|700||on|||||&#8221; header_2_text_color=&#8221;#b59f41&#8243; border_width_left=&#8221;10px&#8221; border_color_left=&#8221;rgba(0,0,0,0)&#8221;]<\/p>\n<h2>New App Aims to Teach Special Relativity Hands-On<\/h2>\n<p>Professor Ira Rothstein hopes to make understanding general relativity a little easier with a new smartphone app that lets anyone experiment with and learn how different aspects of special relativity, like time dilation and length contraction, work.<\/p>\n<p>The app, named Relatively Simple, uses one&#8217;s own movements and animated videos to help make the concepts seem more approachable.<\/p>\n<p>&#8220;The idea is to develop an intuition about special relativity,&#8221; Rothstein said.<\/p>\n<p>Rothstein has developed the app with students from Carnegie Mellon&#8217;s Entertainment Technology Center and with funding from the university&#8217;s Berkman Faculty Development Fund. One day, it may even end up being built into a smartphone game that classes could be designed around.<\/p>\n<p>&#8220;My primary goal was just to do something cool and see if people like it,&#8221; Rothstein said.<\/p>\n<p>[\/et_pb_text][et_pb_button button_url=&#8221;http:\/\/relatively-simple.com\/&#8221; url_new_window=&#8221;on&#8221; button_text=&#8221;Download the Relatively Simple App&#8221; button_alignment=&#8221;center&#8221; _builder_version=&#8221;3.14&#8243; custom_button=&#8221;on&#8221; button_text_color=&#8221;#b59f41&#8243; button_border_color=&#8221;#b59f41&#8243; button_font=&#8221;||||||||&#8221; button_icon=&#8221;%%246%%&#8221; button_on_hover=&#8221;off&#8221; button_text_color_hover=&#8221;#ffffff&#8221; button_bg_color_hover=&#8221;rgba(142,106,48,0.33)&#8221; custom_margin=&#8221;80px|11px|80px|11px|true&#8221; custom_margin_tablet=&#8221;30px||30px||true&#8221; custom_margin_phone=&#8221;30px||30px||true&#8221; custom_margin_last_edited=&#8221;on|tablet&#8221; custom_css_main_element=&#8221;width:100%;&#8221;][\/et_pb_button][\/et_pb_column][et_pb_column type=&#8221;2_5&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_gallery gallery_ids=&#8221;960,962,961&#8243; fullwidth=&#8221;on&#8221; hover_icon=&#8221;%%2%%&#8221; _builder_version=&#8221;3.14&#8243; custom_margin=&#8221;|||&#8221; custom_padding=&#8221;5px|10px|5px|10px||true&#8221; auto=&#8221;on&#8221; auto_speed=&#8221;3000&#8243;][\/et_pb_gallery][et_pb_video src=&#8221;https:\/\/www.youtube.com\/watch?v=-eawxhYqwy8&#8243; _builder_version=&#8221;3.14&#8243; custom_padding=&#8221;5px|10px|5px|10px||true&#8221;][\/et_pb_video][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=&#8221;1&#8243; _builder_version=&#8221;3.14&#8243; background_color=&#8221;#e0e0e0&#8243; box_shadow_style=&#8221;preset6&#8243; custom_padding=&#8221;30px|0px|30px|0px|false|false&#8221;][et_pb_row custom_padding=&#8221;0|0px|0|0px|false|false&#8221; _builder_version=&#8221;3.14&#8243;][et_pb_column type=&#8221;1_2&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_button button_url=&#8221;\/physics\/issue-2019\/feature\/&#8221; button_text=&#8221;Feature: The Future In 2D&#8221; _builder_version=&#8221;3.14&#8243; custom_button=&#8221;on&#8221; button_text_color=&#8221;#e09900&#8243; button_border_color=&#8221;rgba(0,0,0,0)&#8221; button_font=&#8221;||||||||&#8221; button_icon=&#8221;%%179%%&#8221; button_icon_color=&#8221;#e09900&#8243; button_icon_placement=&#8221;left&#8221; button_on_hover=&#8221;off&#8221; button_border_color_hover=&#8221;#e09900&#8243;][\/et_pb_button][\/et_pb_column][et_pb_column type=&#8221;1_2&#8243; _builder_version=&#8221;3.0.47&#8243; parallax=&#8221;off&#8221; parallax_method=&#8221;on&#8221;][et_pb_button button_url=&#8221;\/physics\/issue-2019\/student-notes\/&#8221; button_text=&#8221;Student Notes&#8221; button_alignment=&#8221;right&#8221; _builder_version=&#8221;3.14&#8243; custom_button=&#8221;on&#8221; button_text_color=&#8221;#e09900&#8243; button_border_color=&#8221;rgba(0,0,0,0)&#8221; button_font=&#8221;||||||||&#8221; button_icon=&#8221;%%180%%&#8221; button_icon_color=&#8221;#e09900&#8243; button_on_hover=&#8221;off&#8221; button_border_color_hover=&#8221;#e09900&#8243;][\/et_pb_button][\/et_pb_column][\/et_pb_row][\/et_pb_section]<\/p>\n","protected":false},"excerpt":{"rendered":"<p>THE THEORY BEHIND THE EXPERIMENTIn December 1973, Professor James Russ was working the nightshift at Brookhaven National Lab. His experiment was going well, so he wandered over to the MIT trailer to see what the researchers there were working on. Russ noticed a striking image on the wall. When he asked the researchers in the [&hellip;]<\/p>\n","protected":false},"author":4,"featured_media":0,"parent":720,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_et_pb_use_builder":"on","_et_pb_old_content":"","_et_gb_content_width":"","footnotes":""},"class_list":["post-935","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/magazine.mcs.cmu.edu\/physics\/wp-json\/wp\/v2\/pages\/935","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/magazine.mcs.cmu.edu\/physics\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/magazine.mcs.cmu.edu\/physics\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/magazine.mcs.cmu.edu\/physics\/wp-json\/wp\/v2\/users\/4"}],"replies":[{"embeddable":true,"href":"https:\/\/magazine.mcs.cmu.edu\/physics\/wp-json\/wp\/v2\/comments?post=935"}],"version-history":[{"count":51,"href":"https:\/\/magazine.mcs.cmu.edu\/physics\/wp-json\/wp\/v2\/pages\/935\/revisions"}],"predecessor-version":[{"id":1458,"href":"https:\/\/magazine.mcs.cmu.edu\/physics\/wp-json\/wp\/v2\/pages\/935\/revisions\/1458"}],"up":[{"embeddable":true,"href":"https:\/\/magazine.mcs.cmu.edu\/physics\/wp-json\/wp\/v2\/pages\/720"}],"wp:attachment":[{"href":"https:\/\/magazine.mcs.cmu.edu\/physics\/wp-json\/wp\/v2\/media?parent=935"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}