Seminars

Manipulating spin interactions in 2D materials


van der Waals heterostructures allow for spin proximity effects to the extend not thinkable with conventional nanostructures. Both spin-orbit and exchange interactions can be proximitized intomaterials such as graphene which display nominally only weak spin physics. I will present a few examples of the spin proximity effects and their control by twisting. I will also show that spin interactions can not only be tuned, but they can also be swapped, when the proximity effects are combined with layer polarization, in particular for TMDC/BLG/CGT heterostructures
(arXiv:2005.11058).

Frustrations, memory, and complexity in physics and beyond

The origin of complexity remains one of the most important and, at the same time, the most controversial scientific problems. Earlier attempts were based on theory of dynamical systems (limit circles, strange attractors, etc.) but did not lead to a satisfactory solution of the problem. I believe that a deeper understanding is possible based on a recent development of statistical physics, combining it with relevant ideas from evolutionary biology, AdS/CMT, and machine learning.

Using patterns in magnetic materials as the main example, I discuss some general problems such as (a) a formal definition of pattern complexity [1] and its relation to “holographic complexity” [2]; (b) self-induced spin glassiness due to competing interactions as a way to interpret chaotic patterns [3]; (c) multi-well states intermediate between glasses and ordinary ordered states and their relevance for the problem of long-term memory in complicated systems [4]; and (d) complexity of frustrated quantum spin systems [5]. I will also review a very recent experimental observation of self-induced spin-glass state in elemental neodymium [6] and, in a more speculative way, the role of frustrations and competing interactions in biological evolution and origin of biological complexity [7].

[1] A. A. Bagrov, I. A. Iakovlev, M. I. Katsnelson, and V. V. Mazurenko, Multi-scale structural complexity of natural patterns, arXiv:2003.04632.

[2] D. Ageev, I. Aref’eva, A. A. Bagrov, and M. I. Katsnelson, Holographic local quench and effective complexity, JHEP 08 (2018) 71.

[3] A. Principi and M. I. Katsnelson, Spin glasses in ferromagnetic thin films, Phys. Rev. B 93, 054410 (2016); Self-induced glassiness and pattern formation in spin systems due to long-range interactions, Phys. Rev. Lett. 117, 137201 (2016).

[4] A. Kolmus, M. I. Katsnelson, A. A. Khajetoorians, and H. J. Kappen, Atom-by-atom construction of attractors in a tunable finite size spin array, New J. Phys. 22, 023038 (2020).

[5] T. Westerhout, N. Astrakhantsev, K. S. Tikhonov, M. I. Katsnelson, and A. A. Bagrov, Generalization properties of neural network approximations to frustrated magnet ground states, Nature Commun. 11, 1 (2020).

[6] U. Kamber et al, Self-induced spin glass state in elemental and crystalline neodymium, Science 368, eaay6757 (2020).

[7] M. I. Katsnelson, Y. I. Wolf, and E. V. Koonin, Towards physical principles of biological evolution, Phys. Scripta 93, 043001 (2018); Y. I. Wolf, M. I. Katsnelson, and E. V. Koonin, Physical foundations of biological complexity, PNAS 115, E8678 (2018).

Optically-Controlled Orbitronics on a Triangular Lattice

The propagation of electrons in an orbital multiplet dispersing on a lattice can support anomalous transport phenomena deriving from an orbitally induced Berry curvature. In striking contrast to the related situation in graphene, we find that anomalous transport for an L=1 multiplet on the primitive 2D triangular lattice is activated by easily implemented on site and optically tunable potentials. We demonstrate this for dynamics in a Bloch band where point degeneracies carrying opposite winding numbers are generically offset in energy, allowing both an anomalous charge Hall conductance with the sign selected by off-resonance coupling to circularly polarized light and a related anomalous orbital Hall conductance activated by layer buckling.