Conference Schedule

Unifying non-Markovian characterisation with an efficient and self-consistent framework -- Noise on quantum devices is much more complex than it is commonly given credit. Far from usual models of decoherence, nearly all quantum devices are plagued both by a continuum of environments and temporal instabilities. These induce noisy quantum and classical correlations at the level of the circuit. The relevant spatiotemporal effects are difficult enough to understand, let alone combat. There is presently a lack of either scalable or complete methods to address the phenomena responsible for scrambling and loss of quantum information. Here, we make deep strides to remedy this problem. We establish a theoretical framework that uniformly incorporates and classifies all non-Markovian phenomena. Our framework is universal, assumes no parameter values, and is written entirely in terms of experimentally accessible circuit-level quantities. We formulate an efficient reconstruction using tensor network learning, allowing also for easy modularisation and simplification based on the expected physics of the system. This is then demonstrated through both extensive numerical studies and implementations on IBM Quantum devices, estimating a comprehensive set of spacetime correlations. Finally, we conclude our analysis with applications thereof to the efficacy of control techniques to counteract these effects - including noise-aware circuit compilation and optimised dynamical decoupling. We find significant improvements are possible in the diamond norm and average gate fidelity of arbitrary SU(4) operations, as well as related decoupling improvements in contrast to off-the-shelf schemes.

• Invited Talk

Altermagnets: electronic structures and field-free switching -- The third class of magnetism, dubbed as altermagnetism, has been a recent hot topic in the field of magnetism. Altermagnets have characteristics of both ferromagnetism (FM) and antiferromagnetism (AFM): spin split bands (thus broken time reversal symmetry) and zero net magnetization. These traits may be important in the fundamental scientific point of view as well as for spintronic applications. In this colloquium talk, I first wish to introduce the concept of altermagnetism. I will first talk about ABCs of altermagnetism—collinear AFM (zero net magnetization) and spin split bands (time reversal symmetry breaking) in terms of symmetries. Then, I will discuss the microscopic origin of the spin splitting based on the AFM order and structural distortion. Experimental verification of altermagetism is inherently difficult due to the zero net magnetization as well as domain formation. Yet, evidences for spin split bands can be obtained in some cases. I will introduce our recent ARPES work on an altermagnet MnTe. ARPES data show split bands which merges to a single band above the Neel temperature, strongly indicating the magnetic origin of the splitting. Finally, I will also introduce our recent results on field-free switching of MnTe/Bi2 Te3 hetero structures and potential application for non-volatile memory devices.

• Invited Talk

Universal work extraction in quantum thermodynamics -- Evaluating the maximum amount of work extractable from a nanoscale quantum system is one of the central problems in quantum thermodynamics. Previous works identified the free energy of the input state as the optimal rate of extractable work under the crucial assumption: experimenters know the description of the given quantum state, which restricts the applicability to significantly limited settings. Here, we show that this optimal extractable work can be achieved without knowing the input states at all, removing the aforementioned fundamental operational restrictions. We achieve this by presenting a universal work extraction protocol, whose description does not depend on input states but nevertheless extracts work quantified by the free energy of the unknown input state. Remarkably, our result partially encompasses the case of infinite-dimensional systems, for which optimal extractable work has not been known even for the standard state-aware setting. Our results clarify that, in spite of the crucial difference between the state-aware and state-agnostic scenarios in accomplishing information-theoretic tasks, whether we are in possession of information on the given state does not influence the optimal performance of the asymptotic work extraction.

• Invited Talk

Detecting spin entanglement in quantum matter: experimental pathways towards quantum computation -- Quantum spin liquids are highly correlated states of matter that evade conventional ordering processes and thereby lack any classical order parameter. Their ground state is characterized by emerging long-range entangled quasiparticles that may obey unconventional anyonic quantum statistics, and as such harbor great promise for potential application in fault-tolerant quantum computation. In this talk I will review how we can experimentally track these entangled phases via optical spectroscopy and characterize the nature of emergent quasiparticles and their underlying states. I will compare recent results on several related quantum magnets with different degrees of frustration [1]-[3]. [1] Jeon, Wulferding, et al., Nat. Phys. 20, 435 (2024). [2] Wulferding, Choi, et al., Nat. Commun. 11, 1603 (2020). [3] Wulferding, et al., Commun. Phys. 8, 447 (2025).

• Invited Talk

Speaker: Isha Le Xue Singh

• Oral Session

Ion Modification in Quantum Dots and TMD Devices for Advanced Optoelectronics -- This work investigates ion modification as a strategy for tuning the electronic and optoelectronic properties of low-dimensional materials for advanced device applications. Mid-infrared (MIR) free-electron laser (FEL) irradiation was applied to electrochemically synthesized graphene quantum dots (GQDs) and TiO₂-graphene quantum dot nanocomposites to study ion redistribution and surface-state modification. Following irradiation at 5.76, 8.02, and 9.10 µm, the quantum dots exhibited significant zeta potential inversion together with reduced hydrodynamic size, indicating electrical double-layer restructuring and interfacial ionic rearrangement. Enhanced photoluminescence intensity and slight optical bandgap shifts suggested reduced trap states and improved electronic uniformity, while TEM analysis confirmed preservation of the crystalline structure after irradiation. In parallel, potassium-ion intercalation in transition metal dichalcogenide (TMD) devices was investigated using electrical measurements and density functional theory (DFT) calculations. The results revealed that K-ion incorporation modifies electronic states and carrier transport behavior through charge redistribution and defect interactions within layered semiconductors. Together, these studies demonstrate how ionic engineering can be used to tailor material properties across both colloidal quantum dots and layered electronic materials, with potential applications in perovskite solar cells, sensors, and next-generation optoelectronic devices. Keywords: Quantum Dots, FEL, TMDs, Optoelectronics

• QTRic

Limits of quantum generative models with classical sampling hardness -- Quantum generative machine learning is nowadays seen as a source for quantum advantage due to the prominence of sampling tasks in establishing quantum advantages, both in theory and in experiments. In other words, a quantum device can produce samples from distributions that are unavailable to classical algorithms. For a sampler to become a generative model, it is required that such a model is trained to fit a given input data. In this talk, I will first review the requirements for quantum advantage and the challenge to verify it. Then, we will study the compatibility between such advantage and the trainability of the model. By looking at generative models through the lens of output distributions, we will see that anticoncentration prevents trainability while also being a necessary ingredient for advantage. In contrast, models outputting sparse distributions can be trained. Special cases to enhance trainability will be explored that may open the path for classical algorithms for surrogate sampling. As a final message, we will see that quantum advantage is compatible with generative models, although not rooted in anticoncentration.

• Invited Talk

Exploring altermagnetism in RuO2 via strain and doping -- Altermagnetism has recently emerged as a new class of magnetic order that combines the advantages of both ferromagnets and antiferromagnets. Its compensated antiparallel spin structure, together with crystallographic rotational symmetry, gives rise to distinct magnetic properties, opening new opportunities for next-generation spintronic applications. Whereas directly observing the emergence of the altermagnetic order parameter has been a significant challenge, the magnetic ground state of RuO2 , one of the most important candidates of the altermagnets, remains under debate with conflicting experimental results. In this presentation, I will discuss how the altermagnetism can be stabilized in RuO2 films by anisotropic strain and also by the doping control.

• Invited Talk

Ultrafast Electronic Dynamics in 2D Quantum Materials Revealed by trARPES -- Time- and angle-resolved photoemission spectroscopy (trARPES) enables direct visualization of electronic structures evolving on ultrafast timescales. In this talk, I will present recent results on the nonequilibrium dynamics of two-dimensional quantum materials. By tracking the transient evolution of band structures, we reveal quantum phenomena encoded in the electronic structure. These results demonstrate how ultrafast spectroscopy can uncover and potentially control emergent electronic states in low-dimensional quantum materials.

• Invited Talk

Speaker: Sara Santos, Antonios Varvitsiotis, Saroch Leedumrongwatthanakun

• Oral Session

Chemical potential shift in doped Mott-insulators and capacity enhancement in battery -- This research explores the unique character of strongly correlated systems, specifically Mott-insulators, in the context of advancing battery electrode materials. We investigate the correlation between the proposed chemical potential evolution and charge storage performance in transition metal oxide-based electrodes, hypothesizing that doping a Mott-insulator reduces the Hubbard Coulomb interaction (U), which slows down the chemical potential shift and results in enhanced charge storage capabilities compared to classic band insulators. Experimentally, the study compares the electrochemical performance of lithium-ion batteries (LIBs) with and without a BiFe₀.₉₅Cu₀.₀₅O₃ thin film coating deposited on both LiNi₀.₅Mn₀.₃Co₀.₂O₂ (NMC532) cathodes and graphite anodes. Charging curves for the coated LIBs exhibit a counterintuitive negative slope characterized by negative electronic compressibility (NEC). This NEC effect leads to a significant 34% enhancement in energy density, increasing the first discharge cycle from 190 Wh/kg for pristine LIBs to 255 Wh/kg.

• QTRic