Nav: Home

PKU physicists bridge the equilibrium topological phases and non-equilibrium quantum dynamics

December 21, 2018

How to characterize a topological phase is one of the most fundamental issues in the field of topological quantum physics. Conventionally, a topological phase is characterized by a topological invariant defined for a many-particle ground state in equilibrium. A generic question arises, is there a non-equilibrium characterization of a topological phase defined in equilibrium? This non-trivial question was recently addressed by Xiong-Jun Liu's group at Peking University, who established a non-equilibrium classification theory of equilibrium free-fermion topological phases with integer topological invariants, and bridge equilibrium topological phases and non-equilibrium quantum dynamics. The work was published as a cover paper in the journal Science Bulletin on Sep 29, 2018 (Cover Story: https://www.journals.elsevier.com/science-bulletin/cover-stories/dynamical-classification-of-topological-quantum-phases).

The theory was developed for the generic d-dimensional free-fermion topological phases, with different phases distinguished by different integer topological invariants like the winding numbers or Chern numbers. The non-equilibrium dynamics can be induced by quench, in which process one suddenly tunes the system from an initial trivial phase to a final topological regime. The authors found that, while the bare quench dynamics behave randomly, the time-averaged non-equilibrium dynamics exhibit emergent nontrivial topological pattern in the lower (d-1)-dimensional hypersurfaces, dubbed band-inversion surfaces, of the Brillouin zone. Such emergent topological pattern uniquely corresponds to and so characterizes the bulk topology of the equilibrium phase through an emerging dynamical topological invariant, rendering the generic non-equilibrium characterization theory of topological phases.

This theory bridges the studies of topological phases and non-equilibrium quantum physics. For one side, the work advances the characterization of topological phases from equilibrium theory to non-equilibrium theory, and provides fundamentally new schemes to detect topological states beyond the equilibrium scenarios. The dynamical schemes show explicit advantages over the conventional equilibrium schemes in the detection of topological states. For another side, the work shows insights into the characterization of complex non-equilibrium quantum dynamics by topology. In condensed matter physics, to characterize non-equilibrium quantum physics is usually more complicated than to characterize equilibrium phases. For example, even fixing the initial and final phases for the quench study, there are numerous paths to perform the quench, and in different quench processes the induced bare non-equilibrium quantum dynamics can be sharply different. Importantly, from Liu et al.'s theory all the seemingly distinct quench dynamics manifest identical hidden universal behavior: they exhibit the same emergent nontrivial topological pattern on the band inversion surfaces, and so belong to the same topological class.

A novel issue is that, while the quench dynamics is related to the equilibrium topological phase, the emergent topology of the quantum dynamics by itself is different from the conventional equilibrium topological phases. Many interesting open questions need to be further addressed for the future studies. In particular, as in an equilibrium topological phase there are many nontrivial physics that can be obtained, e.g. the topologically protected gapless boundary modes and defect modes, and the topological stability against local perturbations, etc., are there similar nontrivial topological physics in the emergent topological states of the quench dynamics? Also, can the emergent topological states exist in the correlated systems? All these questions are novel and deserve future studies.
-end-
The proposed theory has already motivated experimental studies of the quench dynamics for ultracold atoms. In particular, applications of this theory to 2D quantum anomalous Hall model and to 3D nodal line semimetal have been reported recently (Phys. Rev. Lett. 121, 250403(2018) and arXiv:1808.07428).

Lin Zhang, Long Zhang, Sen Niu, Xiong-Jun Liu. Dynamical classification of topological quantum phases. Science Bulletin, 2018, 63(21): 1385-1391, doi: 10.1016/j.scib.2018.09.018 https://www.sciencedirect.com/science/article/pii/S209592731830478X

Science China Press

Related Quantum Articles:

Quantum nanoscope
Researchers have studied how light can be used to 'see' the quantum nature of an electronic material.
'Quantum leap' for Liverpool
Physicists from the University of Liverpool have made a huge step forwards towards building a novel experiment to probe the 'dark contents' of the vacuum.
Testing quantum field theory in a quantum simulator
Quantum field theories are often hard to verify in experiments.
Quantum reservoir for microwaves
EPFL researchers use a mechanical micrometer-size drum cooled close to the quantum ground state to amplify microwaves in a superconducting circuit.
Looking for the quantum frontier
Researchers have developed a new theoretical framework to identify computations that occupy the 'quantum frontier' -- the boundary at which problems become impossible for today's computers and can only be solved by a quantum computer.
Quantum mechanics are complex enough, for now...
Physicists have searched for deviations from standard quantum mechanics, testing whether quantum mechanics requires a more complex set of mathematical rules.
Seeing the quantum future... literally
Sydney scientists have demonstrated the ability to 'see' the future of quantum systems and used that knowledge to preempt their demise, in a major achievement that could help bring the strange and powerful world of quantum technology closer to reality.
The sound of quantum vacuum
Quantum mechanics dictates sensitivity limits in the measurements of displacement, velocity and acceleration.
New quantum states for better quantum memories
How can quantum information be stored as long as possible?
Watching quantum jumps
When a quantum system changes its state, this is called a quantum jump.

Related Quantum Reading:

Best Science Podcasts 2019

We have hand picked the best science podcasts for 2019. Sit back and enjoy new science podcasts updated daily from your favorite science news services and scientists.
Now Playing: TED Radio Hour

Changing The World
What does it take to change the world for the better? This hour, TED speakers explore ideas on activism—what motivates it, why it matters, and how each of us can make a difference. Guests include civil rights activist Ruby Sales, labor leader and civil rights activist Dolores Huerta, author Jeremy Heimans, "craftivist" Sarah Corbett, and designer and futurist Angela Oguntala.
Now Playing: Science for the People

#520 A Closer Look at Objectivism
This week we broach the topic of Objectivism. We'll be speaking with Keith Lockitch, senior fellow at the Ayn Rand Institute, about the philosophy of Objectivism as it's taught through Ayn Rand's writings. Then we'll speak with Denise Cummins, cognitive scientist, author and fellow at the Association for Psychological Science, about the impact of Objectivist ideology on society. Related links: This is what happens when you take Ayn Rand seriously Another Critic Who Doesn’t Care What Rand Thought or Why She Thought It, Only That She’s Wrong Quote is from "A Companion to Ayn Rand"