Szemináriumok

Tensor Network algorithms with general non-Abelian symmetries

Időpont: 
2020. 12. 18. 10:15
Hely: 
online (Teams)
Előadó: 
Miklós Werner (BME)

We introduce the notion of non-Abelian tensors, and use them to build a general non-Abelian matrix product state (NA-MPS) ansatz. We construct a non-Abelian time evolving block decimation (NA-TEBD) scheme that uses an arbitrary number of Abelian and non-Abelian symmetries. Our approach increases the speed and memory storage efficiency of matrix product state based computations by several orders of magnitudes, and makes large bond dimensions accessible even on simple desktop architectures. We demonstrate our approach by studying post-quench dynamics in the repulsive SU(3) Hubbard model. We determine time evolution of various local operators and correlation functions and find that interactions turn algebraic charge relaxation into exponential, and  suppress coherent quantum oscillations rapidly.

Secure quantum communications: sky is not the limit

Időpont: 
2021. 01. 25. 14:15
Hely: 
online (Teams)
Előadó: 
László Bacsárdi (BME)

Abstract: "Quantum key distribution, quantum internet, quantum networks – only few selected topics from the growing domain of secure quantum communications. After a short instruction to quantum communications, the lecture will detail selected areas including Quantum Enhanced Networks and Quantum Information Networks and the debate between trusted nodes and untrusted nodes based quantum key distribution (QKD) systems which have terrestrial and/or space segments as well. The related activities at the BME Faculty of Electrical Engineering and Informatics will be highlighted as well including our quantum random number generators, single photon based QKD and continuous variable based QKD experiments."

 

About the speaker: László is an associate professor and the head of the Mobile Communications and Quantum Technologies Laboratory at the BME Department of Networked Systems and Services. He obtained his MSc in computer engineering in 2006, and his PhD in 2012. He became corresponding member of the International Academy of Astronautics (IAA) in 2019. His current research interests are in Industry 4.0, quantum computing and space-based quantum communications.

Collective self-trapping of atoms in a cavity

Időpont: 
2021. 02. 01. 14:15
Hely: 
online in Teams
Előadó: 
András Dombi (Wigner)
We experimentally demonstrate optical dipole trapping of a cloud of cold atoms by means of a dynamically coupled mode of a high-finesse cavity. We show that the trap requires a collective action of the atoms, i.e. a single atom would not be trapped under the same laser drive conditions. The atoms pull the frequency of the mode closer to resonance, thereby allowing the necessary light intensity for trapping into the cavity. The back-action of the atoms on the trapping light mode is also manifested by the non-exponential collapse of the trap.
 

Kibble-Zurek mechanism in the Ising Field Theory

Időpont: 
2021. 02. 05. 10:15
Hely: 
online (Teams)
Előadó: 
Kristóf Hódsági (BME)
How can we describe the formation of order in critical systems? If we tune the control parameters such that the system crosses the critical point, the answer is given by the Kibble-Zurek mechanism (KZM) [1] that predicts universal dependence of observables on the rate of change of the control parameter. In recent years, the focus on quantum critical points [2] demonstrated the validity of the KZM in an extended set of systems. Our work [3] explores the KZM in the Ising Field Theory, where the quantum critical point can be crossed in different directions in the two-dimensional coupling space leading to different scaling laws. Using the Truncated Conformal Space Approach, we investigate the microscopic details of the KZM in terms of instantaneous eigenstates in a genuinely interacting field theory. For different protocols, we demonstrate dynamical scaling in the non-adiabatic time window and provide analytic and numerical evidence for specific scaling properties of various quantities. In particular, we argue that the higher cumulants of the excess heat exhibit universal scaling in generic interacting models for a slow enough ramp.
 
[1] T. W. B. Kibble, Topology of cosmic domains and strings, J. Phys. A: Math. Gen. 9, 1387 (1976); W. H. Zurek, Cosmological experiments in superfluid helium?, Nature 317, 505 (1985).
[2] J. Dziarmaga, Dynamics of a quantum phase transition and relaxation to a steady state, Adv. Phys. 59, 1063 (2010).
[3] K. Hódsági, M. Kormos, Kibble–Zurek mechanism in the Ising Field Theory, SciPost Phys. 9, 055 (2020).

Triplet exciton states in carbon nanotubes

Időpont: 
2021. 02. 12. 10:15
Hely: 
online (Teams)
Előadó: 
Ferenc Simon (BME)
Title: Triplet exciton states in carbon nanotubes: a possible candidate for telecomm compatible qubits
 
Finding a suitable qubit which emits in the near infrared range is the holy grail of ongoing quantum telecommunication research. We propose the recently discovered [1] triplet exciton states in carbon nanotubes for this purpose, whose fundamental properties (energy structure, relaxation time) are now established. I first review the photophysics of best known solid state qubit, the nitrogen-vacancy (NV) center in diamond, which nominally emits in the visible range, far from the so-called telecom frequency windows. I then describe our experimental efforts in developing a specialized optically detected magnetic resonance spectrometer [2], which allowed detection of the otherwise dark triplet excitons in single-walled carbon nanotubes. I show that the nanotube geometry allows for a fine tuning of the emission energies. I present evidence for a singlet-triplet splitting due to quantum confinement and the observation of an exciton energy transfer between nanotubes, which may allow for quantum information transcription.
 
[1] J. Palotás et al. ACS Nano 14, 11254 (2020). (https://arxiv.org/pdf/2009.06314.pdf)
[2] M. Negyedi et al. Rev. Sci. Instrum. 88, 013902 (2017). (https://arxiv.org/pdf/1610.01177.pdf)
 

Interacting topological frequency converter

Időpont: 
2021. 02. 15. 14:15
Hely: 
online (Teams)
Előadó: 
Simon Körber
Non-equilibrium quantum systems host a plethora of topological phenomena. A topological property of quantum dynamics can be related to the effective dimensional extension of the system by time-periodic drives. Following this line of reasoning, it has been shown that a two-level system coupled to two circularly polarized drives can mediate a frequency conversion between the two fields that happens at a topologically quantized rate [1]. In this talk, we will address two types of questions that naturally arise for this kind of quantum system.
 
The first is whether interaction can change the topological features in the dynamically-induced synthetic dimension. We positively answer this question by adding spin-spin interactions to the prototypical model of the topological frequency converter [2]. We demonstrate that the interplay of interaction and synthetic dimension gives rise to striking topological phenomena that have no counterpart in the non-interacting regime. Remarkably, these features already appear for the minimal case of two interacting spins, and can result into an enhancement of frequency conversion as a direct manifestation of the correlated topological response.
 
Given a realization of the topological frequency converter by an externally driven spin qubit, the second question that arises is how environmental effects may affect the dynamical topological response. By studying a quasiperiodically driven central spin model, we demonstrate that the coupling to the surrounding (nuclear) spin bath can lead to an amplification of the frequency conversion that is proportional to the number of (nuclear) spins of the host material.
 
[1] I. Martin, G. Refael, and B. Halperin, Phys. Rev. X 7, 041008 (2017).
 
[2] S. Körber, L. Privitera, J. C. Budich, and B. Trauzettel, Phys. Rev. Research 2, 022023(R) (2020).

Quantum-secured blockchain protocol

Időpont: 
2021. 02. 18. 14:30
Hely: 
online (Teams)
Előadó: 
Aleksey Fedorov (RQC, Moscow)

The blockchain is a distributed ledger platform with high Byzantine fault tolerance, which enables achieving consensus in a large decentralized network of parties who do not trust each other. A paramount feature of blockchains is the accountability and transparency of transactions, which makes it attractive for a variety of applications ranging from smart contracts and finance to manufacturing and healthcare. Blockchain relies on two one-way computational technologies: hash functions and digital signatures. Most blockchain platforms rely on the elliptic curve public-key cryptography or the integer factorization problem to generate a digital signature. The security of these algorithms is based on the assumption of computational complexity of certain mathematical problems. A universal quantum computer would enable efficient solving of these problems, thereby making digital signatures, including those used in blockchains, insecure. A way to guarantee authentication in the quantum era is to use quantum key distribution, which guarantees information-theoretic security based on the laws of quantum physics. Quantum key distribution is able to generate a secret key between two parties connected by a quantum channel (for transmitting quantum states) and a public classical channel (for post processing). We discuss a blockchain platform that is based on quantum key distribution and review possible experimental realizations for such a platform.

 

About the speaker: Dr. Aleksey Fedorov is the Junior Principal Investigator of the research group of Quantum Information Technologies at the Russian Quantum Center in Moscow, Russia. Aleksey studied Computer Science in Moscow, and obtained his PhD in Physics in Paris, in 2017. Currently he and his group studies the potential of quantum systems for information technology. Among other results, Aleksey's group has developed a protocol for a quantum-protected blockchain [Nature (London) 563, 465 (2018); Quantum Sci. Technol. 3, 035004 (2018)]. 

Anomalous Levitation and Annihilation in Floquet Topological Insulators

Időpont: 
2021. 02. 19. 10:15
Hely: 
online (Teams)
Előadó: 
János Asbóth (BME)
Recently, the anomalous Floquet Anderson insulator (AFAI) has attracted significant attention due to the coexistence of chiral edge modes and fully localized bulk. We show[1] that an AFAI can be obtained by time-periodically applying disordered phase "kicks" (via onsite potential) to a clean Chern insulator, a next-nearest neighbor hopping Hamiltonian with staggered flux. By computing the transmission through the system, we find that tuning the time period between the kicks leads to AFAI phases with different topological invariants, even in the limit of complete disorder (uniformly distributed phases). Disorder-induced transitions to these phases occur by "levitation and pair annihilation" of extended states carrying the Chern numbers, but these transitions can be anomalous, with the two annihilating states coming from different Floquet zones. Our results are applicable to a variety of Floquet topological systems, and may provide a more accessible way to construct AFAIs in cold-atom experiments.
 
[1]: H Liu, IC Fulga, J.K. Asboth, Phys. Rev. Research 2, 022048(R), arXiv:2003.02266

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