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<p class="MsoNormal">There are two more Special Colloquia this week in the Smith Seminar Room – a reception will be held 15 minutes prior to each Colloquium. Please mark your calendars to attend these Special talks. Details below:<o:p></o:p></p>
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<p class="MsoNormal">Speaker: Eric Feng (Argonne National Laboratory)<o:p></o:p></p>
<p class="MsoNormal">Date: Wednesday, January 27, 2016<o:p></o:p></p>
<p class="MsoNormal">Time: 11:00 am<o:p></o:p></p>
<p class="MsoNormal">Place: 1080 PRB<o:p></o:p></p>
<p class="MsoNormal">Title: “The Higgs Boson: A portal to New Physics at the LHC”<o:p></o:p></p>
<p class="MsoNormal"><o:p> </o:p></p>
<p class="MsoNormal"><span style="color:#222222;background:white">Abstract: "Our spectacular discovery of the Higgs boson at the CERN Large Hadron Collider in 2012 put the crown jewel on the Standard Model of fundamental particles and interactions. But deep questions
about the unnaturally light Higgs boson mass, matter-antimatter asymmetry, dark matter, and other key features of the universe remain unanswered. Our measurements of the Higgs boson’s couplings and parity, as well as searches for additional Higgs particles,
have given us a bright new spotlight to look for supersymmetry and other exciting new phenomena that may solve these problems. I will describe our latest results in the Higgs sector with the higher-energy ATLAS data, as well as the promising prospects
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<p class="MsoNormal"><span style="color:#222222;background:white">for future discovery.”<o:p></o:p></span></p>
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<p class="MsoNormal">Speaker: Jeanie Lau (UC-Riverside)<o:p></o:p></p>
<p class="MsoNormal">Date: Thursday, January 28, 2016<o:p></o:p></p>
<p class="MsoNormal">Time: 3:30 pm<o:p></o:p></p>
<p class="MsoNormal">Place: 1080 PRB<o:p></o:p></p>
<p class="MsoNormal">Title: “Quantum Transport and Electron Interactions in Few-Layer Atomic Membranes”<o:p></o:p></p>
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<span style="font-size:11.0pt;font-family:"Calibri","sans-serif";color:#222222">Two dimensional materials constitute an exciting and unusually tunable platform for investigation of both fundamental phenomena and electronic applications. Here I will present
our results on transport measurements on high mobility few-layer graphene and phosphorene devices. In bilayer and trilayer graphene devices with mobility as high as 400,000 cm<sup><span style="border:none windowtext 1.0pt;padding:0in">2</span></sup>/V, we
observe intrinsic gapped states at the charge neutrality point, arising from electronic interactions. This state is identified to be a layer antiferromagnetic state with broken time reversal symmetry. In another few-layer graphene system, ABA-stacked trilayer
graphene consists of multiple Dirac bands, where crystal symmetry protects the spin degenerate counter-propagating edge modes resulting in ó<sub><span style="border:none windowtext 1.0pt;padding:0in">xx</span></sub><span class="apple-converted-space"> </span>=
4e<sup><span style="border:none windowtext 1.0pt;padding:0in">2</span></sup>/h. At even higher magnetic fields, the crystal symmetry is broken in by electron-electron interactions and the n=0 quantum Hall state develops an insulating phase with non-monotonic
dependence on temperature and magnetic field. Our findings indicate the role of crystal and spin symmetry in generation of topological phases in multiple Dirac bands. At finite doping, we explore the tunable integer and fractional quantum Hall states and Landau
level crossings in these few-layer systems. Finally, I will present our recent results on quantum oscillations and weak localization in air-stable, few-layer phosphorene devices. Our results underscore the fascinating many-body physics in these 2D membranes.<o:p></o:p></span></p>
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