Condensed Matter/Biophysics
Seminars
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Condensed
Matter/Biophysics Seminars are via Zoom until further notiice
Contact:
Yasu Takano or Dmitrii Maslov |
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January 11
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January 18 (No seminar – MLK Jr
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January 25
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Speaker |
Bo Zhen (Univ. of
Pennsylvania) |
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Title |
Topological
photonics at the nanoscale |
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Abstract |
Topological
photonics has been of great interest due to both fundamental principles and
potential applications. In this talk, I will discuss some of our recent
results in linear and nonlinear nanophotonic structures, where topological
phenomena are achieved. Their applications in photonics integrated circuits
and nonlinear optoelectronic devices will also be discussed. |
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Host |
Xiao-Xiao Zhang |
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February 1 |
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Speaker |
Yin-Chen He
(Perimeter Institute for Theoretical Physics) |
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Title |
Stiefel liquids: from the
Dirac spin liquid to a new critical spin liquid |
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Abstract |
I will talk about a
new type of critical quantum liquids, dubbed Stiefel
liquids, that can emerge from the intertwinement of symmetry breaking orders.
Our theory is based on 2+1 dimensional nonlinear sigma models on target space
SO(N)/SO(4), supplemented with Wess-Zumino-Witten terms. We argue that the Stiefel liquids form a class of critical quantum liquids
with extraordinary properties, such as large emergent symmetries, a cascade
structure, and nontrivial quantum anomalies. We show that the well known deconfined quantum critical point and U(1)
Dirac spin liquid are unified as two special examples of Stiefel
liquids, with N=5 and N=6, respectively.Furthermore,
we conjecture that Stiefel liquids with N>6 are
non-Lagrangian, or in other words are beyond any
mean-field descriptions including parton
constructions. We further predict that the some of the non-Lagragian Stiefel liquids can
be realized as a critical spin liquid in frustrated quantum spin systems, for
example, on triangular or kagome lattice, through
the intertwinement between non-coplanar magnetic orders and
valence-bond-solid orders. |
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Host |
Yasu Takano |
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February 8 |
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Speaker |
Yi Li (Johns Hopkins
Univ.) |
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Title |
Topological
superconducting and many-body orders in doped semimetals |
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Electrons in a
material can synchronize to exhibit collective effects and various ordered
states. I will discuss novel superconducting and density wave orders which
capture the topology of the gap function rather than that of quasiparticle
states only. The nontrivial geometric phases of Cooper pairs and their
non-Abelian generalization lead to fundamentally new topological pairing
orders. |
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Host |
Yuxuan Wang |
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February 15
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February 22 |
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March 1 |
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Speaker |
Jukka Pekola (Aalto Univ., Finland) |
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Title |
Quantum
thermodynamics on superconducting circuits |
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Abstract |
I will start by
introducing ideas and principles of how to realize thermodynamic phenomena
and devices in circuits composed of superconducting elements, including
qubits, combined with heat baths formed of on-chip electronic reservoirs.
This way we have demonstrated quantum-limited heat transport by microwave
photons [1,2], quantum heat valves [3] and rectifiers [4] and ultrasensitive
calorimetric detectors [5]. Towards the end of the talk I will present how we
plan to realize quantum heat engines and refrigerators based on thermodynamic
cycles [6] and considerations on ultimate energy resolution of nanocalorimeters [5,7,8]. [1] M. Meschke, W. Guichard, and J.P. Pekola, Nature 444, 187 (2006). [2] A.V. Timofeev, M. Helle, M. Meschke, M. Möttönen, and J.P. Pekola,
Phys. Rev. Lett. 102, 200801 (2009). [3] A. Ronzani,
B. Karimi, J. Senior, Y.-C. Chang, J. T. Peltonen,
C.D. Chen, and J.P. Pekola, Nat. Phys. 14, 991
(2018). [4] J. Senior, A. Gubaydullin, B. Karimi,
J.T. Peltonen, J. Ankerhold,
J.P. Pekola, Comm. Phys. 3, 40 (2020). [5] B. Karimi,
F. Brange, P. Samuelsson, and J. P. Pekola, Nat. Commun. 11, 367
(2020). [6] B. Karimi and J. P. Pekola, Phys. Rev.
B 94, 184503 (2016). [7] B. Karimi and J.P. Pekola,
Phys. Rev. Lett. 124, 170601 (2020). [8] J. P. Pekola
and B. Karimi, in preparation. |
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Host |
Yasu Takano |
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March 8 |
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Speaker |
Wei Xue (UF) |
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Title |
Superfluid effective
field theory |
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Abstract |
In
this talk, I will present new developments in an effective field theory (EFT)
of helium superfluid. One of the motivation to build
this framework is to understand a test particle scattering of the superfluid
with its de Broglie wavelength shorter than the average helium spacing. The
scattered helium atom will produce a few to thousands of quasi-particles. Due
to mixing with different momentum scales, a naive EFT of the superfluid
breaks down, but a novel EFT is introduced to describe how helium atoms decay
to quasi-particles and quasi-particles are thermalized. |
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Host |
Tarek Saab |
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March 15
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March 22 |
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Speaker |
Pinshane Huang (Univ.
Illinois Urbana-Champaign) |
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Title |
How stiff are 2D materials?
Designing ultrasoft electronic materials using
insights from electron microscopy |
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Abstract |
Understanding the deformation and bending of
two-dimensional (2D) materials is critical for the realization of
next-generation electronics and nanomechanical devices. For example, while
the mechanics of few-layer graphene have been studied for more than a decade,
there is still no consensus on basic properties such as its bending stiffness
and how it scales with thickness. In
addition, defect and strain
engineering of 2D materials is an emerging area of research, where
homogeneous or heterogeneous alloying can stabilize exotic electronic phases
such as Weyl semimetals or pattern the properties of 2D nanoelectronics and
optoelectronics on the nanoscale. Electron microscopy provides a powerful
platform for addressing these challenges by enabling measurements of the
conformation and strain of 2D materials at atomic resolution. In this talk, I
will discuss our work using aberration-corrected scanning transmission
electron microscopy (STEM) in order to probe and quantify these deformations
in 2D materials at the atomic scale.
This work is divided into two areas: 1) using machine learning to
expand the precision of atomic resolution STEM in order to visualize local picometer-scale strain
fields and understand how single-atom defects interact with the surrounding
lattice and 2) using STEM in combination with mechanical modeling to reveal
an unusual, slip-mediated softening of graphene and other 2D materials. Our results indicate
that the bending stiffness of few layer graphene can be orders of magnitude
smaller than previously thought and provide a new lower limit for the
fabrication of ultra-soft, high mobility electronic nanodevices based on 2D
materials. As a bonus, I will also talk about our recent work imaging small
molecules at atomic resolution on graphene substrates. |
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Host |
Kathryn McGill |
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March 29 |
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Speaker |
Eduardo Fradkin (Univ. Illinois Urbana-Champaign) |
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Title |
Duality in condensed
matter and high energy physics |
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Abstract |
I
will discuss the subject of duality transformations in condensed matter and
in high energy physics both from a historical and modern perspectives. I will
focus on the role of recently discovered dualities in 2+1 dimensions in the
problem of the quantum Hall plateau transitions and in the theories of
non-Abelian quantum Hall states. |
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Host |
Yuxuan Wang |
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April 5 |
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April 12 |
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Speaker |
Serena Bradde (American Physical Society) |
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Title |
The dimension of a
complex system: a physicist perspective |
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Abstract |
A
fundamental problem in science is uncovering the effective number of dynamical
degrees of freedom in a complex system. For many real systems, the dimension
changes on the spatio-temporal scale at which the system is observed, making
the problem of dimensional reduction hard to solve. In this talk, I will
propose an approach to describe ‘effectively’ the behavior of complex systems
by drawing an analogy with the Renormalization Group. |
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Host |
Purushottam Dixit |
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April 19 |
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