Harvard University Department of Physics

How Eggs Got Their Shapes

The evolution of the amniotic egg — complete with membrane and shell — was key to vertebrates leaving the oceans and colonizing the land and air. Now, 360 million years later, bird eggs come in all shapes and sizes...

Toward Mass-Producible Quantum Computers

artist's representation of a diamond-based quantum computer

Quantum computers are experimental devices that offer large speedups on some computational problems. One promising approach to building them involves harnessing nanometer-scale atomic defects in diamond materials...

Congratulations to the 2016-17 Physics Graduates!

group photo of graduating physics PhD students

This year's graduating seniors and PhDs are...

UPCOMING EVENTS

Today

CMP Special Seminar: Andrea Young (UCSB), hosted by Philip Kim
Start: 02:00pm - End: 03:00pm
- 02:00pm
- Title: New Fractional quantum Hall states in graphene heterostructures
  
  Abstract: I will discuss magnetocapacitance experiments from a new generation of ultra-clean graphene heterostructures, realized by replacing conventional gate metallization with single crystal graphite flakes. In the first part of the talk, I will discuss bilayer graphene as a platform for exploring the half-filled Landau level (LL), focusing on the observation of robust, single component even-denominator fractional quantum Hall states at filling ν=-5/2, -1/2, 3/2, and 7/2. Numerical simulations of the blayer graphene ZLL suggest this state is in the Pfaffian phase, consistent with the experimentally observation of a 7/13 and weak 8/17 incompressible state—predicted Pfaffian ‘daughter’ states. Unlike in conventional systems, magnetic field directly changes the single particle wavefunction, tuning the mixture of lowest and first LL amplitudes within a single component level. We observe this pseudopotential tuning as rise and subsequent near-collapse of the ½ gap at high field, indicating the presence of a nearby Pfaffian-composite fermi liquid transition. A similar transition can be tuned by engineering a level crossing between N=0 and N=1 LLs in different valleys. Here, we find that the Pfaffian-CFL transition is mediated by an unexpected gapped phase, characterized by large valley imbalance but a persistent charge gap.
  
  In the second part of the talk, I will describe the effects of a superlattice on the nature of the fractional quantum Hall effect. At high magnetic field in devices where the graphene is aligned with one or both adjacent hBN crystals, a substrate-induced moiré superlattice gives rise to a variety of Hofstadter bands with Chern numbers . Trajectories of energy gaps in the density () magnetic flux () plane follow linear trajectories parameterized by integers and , Contrary to single particle theory—which predicts a fractal band structure, with each band subdivided into a recursive hierarchy of minibands—we find robust incompressible states at fractional filling of these Chern bands, characterized by fractional and/or fractional . Basic arguments, supplemented by numerical DMRG calculations, support two kinds of correlated states: states with integer and fractional break lattice symmetry, while states with both fractional and fractional do not break lattice symmetry. These latter, known as fractional Chern insulators, constitute a fractional quantum Hall effect ‘without Landau levels.’
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Tomorrow

Prof. Mathias Kolle - MIT
Start: 05:30pm - End: 07:00pm
- 05:30pm
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