桃花直播

桃花直播 researchers鈥 findings featured in Nature article on proton 鈥榖roken symmetry鈥

桃花直播 researchers鈥 findings featured in Nature article on proton 鈥榖roken symmetry鈥

Contact: Sarah Nicholas

STARKVILLE, Miss.鈥擜 桃花直播 State faculty member鈥檚 research on asymmetry in protons is introduced in today鈥檚 [Feb. 24] edition of Nature, a national publication featuring top-quality peer-reviewed research in all fields of science.

Along with their research collaborators, Associate Professor Lamiaa El Fassi of 桃花直播鈥檚 Department of Physics and Astronomy聽and Catherine Ayuso,聽an 桃花直播 post-doctoral聽research associate, have written a paper on the study 鈥淭he asymmetry of antimatter in the proton.鈥 It focuses on how the proton, a positively charged particle that exists at the center of every聽atomic nucleus, displays 鈥渂roken symmetry,鈥 which describes an object that seems symmetric but isn鈥檛.聽

Lamiaa El Fassi
Lamiaa El Fassi
Catherine Ayuso
Catherine Ayuso

To read about the research, visit

Physicists at the U.S. Department of Energy鈥檚 Argonne National Laboratory and their collaborators at various U.S.,聽Japan and Taiwan聽universities,聽recently investigated the intricacies of this known broken symmetry through an experiment conducted at DOE鈥檚 Fermi National Accelerator Laboratory. The results of the experiment could shift research of the proton by reviving previously discarded theories of its inner workings.

鈥淒r. El Fassi鈥檚 findings are yet another example of how 桃花直播 researchers contribute significantly to the body of science and make extraordinary discoveries鈥攄iscoveries that are capable of changing the trajectory of the field or creating paradigm shifts,鈥 said Giselle Thibaudeau, associate dean for research in 桃花直播鈥檚 College of Arts and Sciences. 鈥淲e are extremely proud of Dr. El Fassi and her collaborative team and look forward to their future successes in nuclear physics. In particular, we look forward to hearing more about the asymmetry in the proton, which until this recent discovery has been assumed to display symmetry.鈥

Graphical representation of the proton.
Graphical representation of the proton. The large spheres represent the three valence quarks, the small spheres represent the other quarks that make up the proton, and the springs represent the nuclear force holding them together. (Image by Brookhaven National Laboratory)

桃花直播 Physics Department Head Mark Novotny said humans exhibit a bilateral symmetry, in that their left and right halves are identical.聽鈥淎ctually, this is broken symmetry,鈥 Novotny explained, 鈥渋n that their left and right sides are only approximately the same if they were reflected in a mirror.聽The paper in Nature of Drs. El-Fassi and Ayuso, as well as their collaborators, studied broken symmetry of the proton.聽Understanding the proton is important because we are, by mass, about one-half protons. Science advances by constantly advancing theories and checking those theories through experimentation in order to understand nature, and then utilizing that understanding in applications.鈥

El Fassi began the long-term project as a postdoctoral fellow at Rutgers University and continued her research when she joined 桃花直播鈥檚 faculty as an experimental nuclear physicist in 2014.聽

鈥淭his study is intriguing because it aims to unravel the dynamics of the evanescent low-momentum pairs of quark and anti-quark鈥攖he antiparticle counterpart of each quark flavor with similar mass but opposite electric charge鈥攊n the sea of the proton by studying the asymmetry of two anti-quark flavors, anti-up and anti-down quarks, in terms of their momentum fractions,鈥 El Fassi said.

Graphic of quarks annihilating (left red lines), producing a photon (green middle line), and producing two muons (right magenta lines).
Graphic of quarks annihilating (left red lines), producing a photon (green middle line), and producing two muons (right magenta lines). Scientists detected these muons to gain insight into the quark asymmetry of the proton. (Image by Paul Reimer, Argonne National Laboratory)

She explained that the current research conclusions oppose the 1990s experimental聽results that originally indicated anti-up quark dominance over anti-down quark at higher momentum fractions. El Fassi鈥檚 research also revives older theoretical models which did not support the 1990s conclusions but 鈥減erfectly agree鈥 with the current scenario.

鈥淭his is just the beginning of the sea quarks investigations聽journey because Catherine Ayuso and I are pursuing a study聽probing the correlation between the antiquark鈥檚 orbital angular motion and the proton spin鈥攁n intrinsic聽quantum property describing the internal revolution about its axis of symmetry鈥攊n the聽SeaQuest successor聽experiment, the 鈥楽pinQuest experiment.鈥欌

El Fassi鈥檚 work is supported in part by 桃花直播鈥檚 College of Arts and Sciences and university start-up funds as well as the Department of Energy鈥檚 Office of Nuclear Physics award.聽

El Fassi received her Ph.D. in 2008 from Mohammad V University in Rabat Morocco jointly with Argonne National Laboratory in Lemont, Illinois. Ayuso earned her Ph.D. from Michigan University in 2020. Her doctoral research with SeaQuest involved analyzing the experimental data of this research project. She is working at 桃花直播 with El Fassi for a three-year postdoctoral fellowship.

桃花直播鈥檚 College of Arts and Sciences includes more than 5,000 students, 323 full-time faculty members, nine doctoral programs, 14 master鈥檚 programs, and 27 undergraduate academic majors offered in 14 departments. 桃花直播 is classified by the Carnegie Classification of Institutions of Higher Education as a 鈥淰ery High Research Activity鈥 doctoral university. Complete details about the College of Arts and Sciences or the physics department may be found at or . 聽

桃花直播 is 桃花直播鈥檚 leading university, available online at . 聽