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BEGIN:VEVENT
DTSTART;TZID=Europe/Berlin:20251118T160000
DTEND;TZID=Europe/Berlin:20251118T170000
DTSTAMP:20260430T182910
CREATED:20251114T110811Z
LAST-MODIFIED:20251114T112843Z
UID:6157-1763481600-1763485200@www.trr360.de
SUMMARY:TRR 360 Sonderseminar: Computational design of quantum materials using density functional theory and beyond Manish Verma
DESCRIPTION:Computational design of quantum materials using density functional theory and beyond \n\n\n\n \n\n\n\nDr. Manish Verma \n\n\n\n \n\n\n\n\n\n\n\nInstitute for Theoretical Physics and AstrophysicsComputational Quantum MaterialsJulius-Maximilians-Universität Würzburg \n\n\n\n\n\n\n\n \n\n\n\nComputational design of quantum materials using density functional theory (DFT) and many-body techniques-both perturbative and non-perturbative\, has become a powerful tool for exploring key physical phenomena such as strong correlations\, metal-to-insulator transitions (MIT)\, magnetism\, and thermoelectricity etc. In this direction\, designing novel electronic properties in artificial transition metal oxide (TMO) heterostructures\, distinct from their bulk counterparts\, has emerged as a new paradigm enabled by modern layer-by-layer growth techniques and the unique nature of d-electrons. I will start my talk by discussing the mechanisms driving the MIT and magnetism in ultrashort-period superlattices (SL)\, namely (SrVO3)1/(SrTiO3)1(001) [1\, 2] and (LaNiO3)1/(LaAlO3)1(001) [3]\, where confinement and epitaxial strain play fundamental roles. Subsequently\, I will present the MIT in Ca-doped LaMnO3\, which arises from the interplay between strain and chemical doping [4]. TMO-based SL are also known to exhibit high thermoelectric response\, in addition to their environmental friendliness and stability. In this context\, I will discuss the doping-induced robust p-type thermoelectric response in ultrashort-period (SrMnO3)1/(SrTiO3)1(001) SL\, obtained by employing Boltzmann transport theory within constant-relaxation time approach. Next\, I will then present my results on strategies for reducing lattice thermal conductivity in artificial oxide superlattices\, obtained using many-body perturbation theory calculations of phonon-phonon interactions. Transition-metal oxides are further known to display strong correlation effects due to their d-electrons. In this regard\, LiV2O4 stands out as an enigmatic heavy fermion compound lacking localized f-orbital states. I will present DFT combined with dynamical mean-field theory (DFT+DMFT) results that elucidate the origin of heavy-fermion behavior\, supported by angle-resolved photoemission spectroscopy (ARPES) measurements [5]. \n\n\n\n\n\n\n\n[1] M. Verma\, B. Geisler\, and R. Pentcheva\, Phys. Rev. B 100\, 165126 (2019).[2] M. Verma and R. Pentcheva\, Phys. Rev. Research 4\, 033013 (2022).[3] M. Verma and R. Pentcheva\, Phys. Rev. Research 6 (1)\, 013189 (2024).[4] S. S. Hong et al.\, Science 368\, 71 (2020).[5] D. Oh et al.\, Proceedings of the National Academy of Sciences 122 (45)\, e2518213122 (2025). \n\n\n\n\n\n\n\nVenue
URL:https://www.trr360.de/event/trr-360-sonderseminar-computational-design-of-quantum-materials-using-density-functional-theory-and-beyond-manish-verma/
LOCATION:University of Augsburg\, Room S-288
CATEGORIES:Sonderseminar
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Berlin:20250708T171500
DTEND;TZID=Europe/Berlin:20250708T181500
DTSTAMP:20260430T182910
CREATED:20250702T084916Z
LAST-MODIFIED:20250702T085154Z
UID:5390-1751994900-1751998500@www.trr360.de
SUMMARY:TRR 360 Sonderseminar: Phase diagram of the heavy-fermion superconductor YbRh2Si2 at ultra-low temperatures Manuel Brando
DESCRIPTION:Phase diagram of the heavy-fermion superconductor YbRh2Si2 at ultra-low temperatures \n\n\n\nDr. Manuel Brando \n\n\n\nMax-Planck-Institute for Chemical Physics of Solids\, Dresden \n\n\n\n \n\n\n\n\n\n\n\nVenue
URL:https://www.trr360.de/event/trr-360-sonderseminar-phase-diagram-of-the-heavy-fermion-superconductor-ybrhsub2-subsi2-at-ultra-low-temperatures-manuel-brando/
LOCATION:University of Augsburg\, Room S-254 + Zoom
CATEGORIES:Sonderseminar
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Berlin:20250703T110000
DTEND;TZID=Europe/Berlin:20250703T120000
DTSTAMP:20260430T182910
CREATED:20250702T103620Z
LAST-MODIFIED:20250702T103621Z
UID:5401-1751540400-1751544000@www.trr360.de
SUMMARY:TRR 360 Sonderseminar: Emergence of novel quantum phases in Yb-based effective spin-1/2 systems with competing exchange interactions Takahiro Onimaru
DESCRIPTION:Emergence of novel quantum phases in Yb-based effective spin-1/2 systems with competing exchange interactions \n\n\n\nProf. Dr. Takahiro Onimaru \n\n\n\nHiroshima University\, Japan \n\n\n\n \n\n\n\n\n\n\n\nVenue
URL:https://www.trr360.de/event/trr-360-sonderseminar-emergence-of-novel-quantum-phases-in-yb-based-effective-spin-1-2-systems-with-competing-exchange-interactions-takahiro-onimaru/
LOCATION:University of Augsburg\, Room S-254 + Zoom
CATEGORIES:Sonderseminar
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Berlin:20250515T140000
DTEND;TZID=Europe/Berlin:20250515T150000
DTSTAMP:20260430T182910
CREATED:20250507T154835Z
LAST-MODIFIED:20250507T155246Z
UID:5190-1747317600-1747321200@www.trr360.de
SUMMARY:TRR 360 Sonderseminar: Probing ultrafast Electron and Spin Dynamics in Momentum\, Space\, and Time Martin Aeschlimann
DESCRIPTION:Probing ultrafast Electron and Spin Dynamics in Momentum\, Space\, and Time \n\n\n\nProf. Dr. Martin Aeschlimann \n\n\n\nDepartment of Physics and Research Center OPTIMAS\, RPTU Kaiserslautern-Landau \n\n\n\n \n\n\n\nCompeting interactions of spin with charge and lattice\, determined by the spin-orbit interaction\, give rise to rich phase diagrams of states in novel correlated electron materials. In such materials\, magnetically ordered phases are very often in direct competition with other ordered phases\, such as a spin- or charge-ordered phase. Unfortunately\, the dominant interaction responsible for the formation of a particular phase is often difficult to determine at thermal equilibrium\, so that a fundamental understanding of the underlying competing interactions is out of reach using static measurements. Time-resolved spectroscopy techniques have the potential to overcome these limitations by temporally driving the material system out of equilibrium. The subsequent relaxation pathways are then determined by the spin-charge lattice interactions\, which can be studied using different photoemission techniques. In this talk I will show how recent developments in ultrafast light sources and photoemission detector technology have paved the way for a completely new generation of time- and spin-resolved photoemission experiments. With this tool at hand we can directly observe the temporal evolution of excited carriers and spins in energy\, momentum space and time\, providing an unprecedented insight into the fundamental energy and (angular) momentum dissipation mechanisms even in complex condensed matter. \n\n\n\n\n\n\n\nVenue
URL:https://www.trr360.de/event/trr-360-sonderseminar-probing-ultrafast-electron-and-spin-dynamics-in-momentum-space-and-time-martin-aeschlimann/
LOCATION:University of Augsburg\, Room S-288 + Zoom
CATEGORIES:Sonderseminar
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Berlin:20250410T140000
DTEND;TZID=Europe/Berlin:20250410T150000
DTSTAMP:20260430T182910
CREATED:20250409T173953Z
LAST-MODIFIED:20250410T182623Z
UID:5114-1744293600-1744297200@www.trr360.de
SUMMARY:TRR 360 Sonderseminar: Localized Magnons in the Generalized Model of the Sawtooth Chain with Dzyaloshinskii-Moriya Interactions Vadim Ohanyan
DESCRIPTION:Localized Magnons in the Generalized Model of the Sawtooth Chainwith Dzyaloshinskii-Moriya Interactions \n\n\n\nDr. Vadim Ohanyan \n\n\n\nYerevan State University\, Armenia \n\n\n\n \n\n\n\n\n\n\n\nVenue
URL:https://www.trr360.de/event/trr-360-sonderseminar-localized-magnons-in-the-generalized-model-of-the-sawtooth-chain-with-dzyaloshinskii-moriya-interactions-vadim-ohanyan/
LOCATION:University of Augsburg\, Room S-439
CATEGORIES:Sonderseminar
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Berlin:20241030T090000
DTEND;TZID=Europe/Berlin:20241030T103000
DTSTAMP:20260430T182910
CREATED:20241024T142401Z
LAST-MODIFIED:20241024T144026Z
UID:4207-1730278800-1730284200@www.trr360.de
SUMMARY:Introduction to the electronic lab book ELabFTW
DESCRIPTION:An introduction to the electronic lab book eLabFTW is scheduled for next Wednesday\, October 31st at 9:00 a.m. in the seminar room of EPII (room 344\, north) at the University of Augsburg.This will be a hybrid seminar\, conducted in parallel online.The Zoom link and login details are provided by email to all TRR 360 staff members.
URL:https://www.trr360.de/event/introduction-the-the-electronic-lab-book-elabftw/
CATEGORIES:Sonderseminar
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Berlin:20240628T100000
DTEND;TZID=Europe/Berlin:20240628T110000
DTSTAMP:20260430T182910
CREATED:20240627T140038Z
LAST-MODIFIED:20240627T141259Z
UID:3372-1719568800-1719572400@www.trr360.de
SUMMARY:TRR 360 Sonderseminar: Optimization and Application for Cryogenic Magnetic Refrigeration Using Yb-based Intermetallic Compounds Yasuyuki Shimura
DESCRIPTION:Optimization and Application for Cryogenic Magnetic Refrigeration Using Yb-based Intermetallic Compounds\nProf. Dr. Yasuyuki Shimura\nHiroshima University\, Japan \n\n\n\n \n\n\n\n\n\n\n\nVenue
URL:https://www.trr360.de/event/trr-360-sonderseminar-optimization-and-application-for-cryogenic-magnetic-refrigeration-using-yb-based-intermetallic-compounds-yasuyuki-shimura/
LOCATION:University of Augsburg\, Room 242-R
CATEGORIES:Sonderseminar
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Berlin:20240627T140000
DTEND;TZID=Europe/Berlin:20240627T150000
DTSTAMP:20260430T182910
CREATED:20240625T060720Z
LAST-MODIFIED:20240625T061917Z
UID:3342-1719496800-1719500400@www.trr360.de
SUMMARY:TRR 360 Sonderseminar: Ultrafast spin-orbitronics with terahertz electromagnetic pulses Tobias Kampfrath
DESCRIPTION:Ultrafast spin-orbitronics with terahertz electromagnetic pulses\nTobias Kampfrath\nFreie Universität Berlin and Fritz Haber Institute of the Max Planck Society\, Berlin \n  \nTo take advantage of the electron spin in future electronics\, spin angular momentum needs to be transported and detected. Electric fields and temperature gradients have been shown to efficiently drive spin transport at megahertz and gigahertz frequencies. However\, to probe the initial elementary steps that lead to the formation of spin currents\, we need to launch and measure transport on much faster\, i.e.\, femtosecond time scales. \nTo achieve this goal\, we apply optical femtosecond laser pulses to induce a spin voltage in a metallic ferromagnetic layer F [1]. The resulting spin current into an adjacent layer is measured by conversion into a charge current in a layer N and detection of the concomitantly emitted terahertz electromagnetic pulse [2]. Interesting applications such as terahertz spin-conductance spectroscopy [3] and the generation of ultrashort terahertz electromagnetic pulses emerge [4]. In all cases\, the emitted terahertz signal arises from regions close to the F/N interface\, thereby making spintronic terahertz emission very interface-sensitive [5] \nThis methodology can be transferred from the spin to the so far highly unexplored orbital angular momentum of electrons. We obtain new insights into orbitronic phenomena on their natural time scales\, for example\, time-domain signatures of giant propagation lengths of orbital currents in tungsten [6]. \nFinally\, one can implement a reciprocal experimental scheme and use intense terahertz electromagnetic pulses to drive electric currents and control magnetic order on ultrafast time scales through\, for example\, Néel spin-orbit torques [7]. \n  \nReferences[1] Rouzegar et al.\, Phys. Rev. B 106\, 144427 (2022)[2] Kampfrath et al.\, Nature Nanotech. 8\, 256 (2013)[3] Rouzegar et al.\, arXiv:2305.09074 (2023)[4] Seifert et al.\, Nature Photon. 10\, 483 (2016); Rouzegar et al.\, Phys. Rev. Appl. 19\, 034018 (2023)[5] Gueckstock et al.\, Advanced Materials 33\, 2006281 (2021)[6] Seifert et al.\, Nature Nanotech. 18\, 1132-1138 (2023)[7] Behovits et al.\, Nature Communications 14\, 6038 (2023) \n\n\n\n\n\n\nFigure: Schematic of optically driven spin-orbitronic emission of ultrabroadband terahertz electromagnetic pulses from a generic F|N thin-film stack. 𝑴 is the magnetization of layer F. \n\n\n\n\n\n\n\nVenue
URL:https://www.trr360.de/event/trr-360-sonderseminar-ultrafast-spin-orbitronics-with-terahertz-electromagnetic-pulses-tobias-kampfrath/
LOCATION:University of Augsburg\, Room S-288 + Zoom
CATEGORIES:Sonderseminar
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Berlin:20240611T160000
DTEND;TZID=Europe/Berlin:20240611T170000
DTSTAMP:20260430T182910
CREATED:20240605T123744Z
LAST-MODIFIED:20240610T133953Z
UID:2795-1718121600-1718125200@www.trr360.de
SUMMARY:TRR 360 Sonderseminar: Structure and magnetism of LMO/SMO superlattices Vasily Moshnyaga
DESCRIPTION:Structure and magnetism of LMO/SMO superlattices \nProf. Dr. Vasily MoshnyagaI. Physikalisches InstitutGeorg-August-Universität Göttingen \nHeterostructures of strongly correlated oxides\, like superlattices (SLs) of (LaMnO3)m/(SrMnO3)n ((LMO)m/(SMO)n)\, provide a rich platform for searching emergent phases at the interfaces as well as to design artificial electronically/chemically inhomogeneous materials to study the manifestations of electron-spin-lattice correlations in reduced dimensions. We studied the structure and magnetism of the LMO/SMO SLs prepared on SrTiO3(100) substrates by metalorganic aerosol deposition (MAD) technique. The role of interfacial charge transfer in the high-TC emergent ferromagnetism and the interrelations between the octahedral tilt/rotation angle\, controlled by LMO/SMO ratio\, and magnetic/thermal properties have been elucidated. Further on\, we have grown LMO/SMO SLs with gradual La/Sr compositional modulations on the scale 5-10 u.c. and studied their role in the development of high- and low-temperature magnetic phases. We propose a route to grow strongly correlated heterostructures with modulated electronic properties at the nanoscale. \n\n\n\n\n\n\nVenue
URL:https://www.trr360.de/event/trr-360-sonderseminar-structure-and-magnetism-of-lmo-smo-superlattices-vasily-moshnyaga/
LOCATION:University of Augsburg\, Room S-288 + Zoom
CATEGORIES:Sonderseminar
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Berlin:20240611T140000
DTEND;TZID=Europe/Berlin:20240611T150000
DTSTAMP:20260430T182910
CREATED:20240610T115811Z
LAST-MODIFIED:20240610T133420Z
UID:2801-1718114400-1718118000@www.trr360.de
SUMMARY:TRR 360 Sonderseminar: Microwave spectrum analyzer based on a rapidly tuned spin-torque nano-oscillator Andrei Slavin
DESCRIPTION:Microwave spectrum analyzer based on a rapidly tuned spin-torque nano-oscillator \nAndrei Slavin \nDepartment of Physics\, Oakland University\, Rochester\, MI 48309\, USA \nA spintronic method of ultra-fast broadband microwave spectrum analysis is proposed. It uses a rapidly tuned spin torque nano-oscillator (STNO) and does not require injection locking. This method treats an STNO generating a microwave signal as an element with an oscillating resistance. When an external signal is applied to this “resistor” for analysis\, it is mixed with the signal generated by the STNO. The resulting mixed voltage contains the “sum” and “difference” frequencies\, and the latter produces a DC component when the external frequency matches the frequency generated by the STNO.  The mixed voltage is processed using a low pass filter to exclude the “sum” frequency components and a matched filter to exclude the dependence of the resultant DC voltage on the phase difference between the two signals. It is found analytically and by numerical simulation that the proposed spectrum analyzer has a frequency resolution at a theoretical limit in a real-time scanning bandwidth of 10 GHz and a frequency scanning rate about 20 MHz /ns\, while remaining sensitive to signal power as low as the Johnson-Nyquist thermal noise floor. \n    \n Andrei Slavin received PhD degree in Physics in 1977 from the St.Petersburg Technical University\, St. Petersburg\, Russia.  Dr. Slavin developed a state-of-the-art theory of spin-torque oscillators\, which has numerous applications in the theory of current-driven magnetization dynamics in magnetic nanostructures. His current research support includes multiple grants from the U.S. Army\, DARPA\, SRC and the National Science Foundation. This research involves international collaborations with leading scientists in many countries\, including Germany\, Ukraine\, France\, Italy\, and the United States. Dr. Slavin is a frequently invited speaker at magnetism conferences around the world.  \n   Andrei Slavin is Fellow of the American Physical Society\, Fellow of the IEEE\, and Distinguished Professor  and Chair of the Physics Department at the Oakland University\, Rochester\, Michigan\, USA. \n\n\n\n\n\n\nVenue
URL:https://www.trr360.de/event/trr-360-sonderseminar-microwave-spectrum-analyzer-based-on-a-rapidly-tuned-spin-torque-nano-oscillator-andrei-slavin/
LOCATION:Technical University Munich + Zoom
CATEGORIES:Sonderseminar
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Berlin:20240311T113000
DTEND;TZID=Europe/Berlin:20240311T123000
DTSTAMP:20260430T182910
CREATED:20240209T140608Z
LAST-MODIFIED:20240507T214038Z
UID:1274-1710156600-1710160200@www.trr360.de
SUMMARY:TRR 360 Sonderseminar: Magnetic field versus temperature phase diagram of an effective spin-1/2 zigzag chain in a magnetic semiconductor YbCuS2 Takahiro Onimaru
DESCRIPTION:Magnetic field versus temperature phase diagram of an effective spin-1/2 zigzag chain in a magnetic semiconductor YbCuS2 \nProf. Dr. Takahiro Onimaru\nGraduate School of Advanced Science and Engineering\, Hiroshima University\, Japan \n\n\n\n\n\n\nVenue
URL:https://www.trr360.de/event/trr360-sonderseminar-magnetic-field-versus-temperature-phase-diagram-of-an-effective-spin-1-2-zigzag-chain-in-a-magnetic-semiconductor-ybcus2-takahiro-onimaru-2/
LOCATION:University of Augsburg\, Room S-288 + Zoom
CATEGORIES:Sonderseminar
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Berlin:20231108T170000
DTEND;TZID=Europe/Berlin:20231108T180000
DTSTAMP:20260430T182910
CREATED:20240209T113946Z
LAST-MODIFIED:20240507T214924Z
UID:1246-1699462800-1699466400@www.trr360.de
SUMMARY:TRR 360 Sonderseminar: The unusual electron transport in metallic Kagome nets Philip J. W. Moll
DESCRIPTION:The unusual electron transport in metallic Kagome nets \nProf. Dr. Philip J. W. Moll \nMax Planck Institute for the Structure and Dynamics of Matter \n  \nMaterials that can host different states of electronic order form a recurring theme in physics and \nmaterials science\, and they are of particular interest if they are coupled strongly. A famous \nexample are ferroelectrics\, in which electric polarization and magnetism not only coexist but are \nstrongly linked. This both unveils a rich physics of correlated states\, and also opens unexpected \napplication avenues as the coupling promises to manipulate one state by a stimulus that primarily \nacts on another – say switching magnetism using electric fields. \nRecently\, materials based on the structural motif of the Kagome web have attracted significant \nattention for their tendency to host such strongly coupled phases. In particular\, the centro- \nsymmetric layered Kagome metal (K\,Cs)V3Sb5 have entered the focus of experimental and \ntheoretical research. They host a charge-density-wave type transition at elevated temperatures \n~100K\, followed by a superconducting transition at 3K (exact values depend on composition). \nYet there is another type of electronic order which thus far eludes exact microscopic \nidentification. A series of experimental probes detects the onset of anomalous behavior around \nT’~30-40K\, including thermal Hall\, µSR\, NMR\, magnetic torque\, Kerr rotation. The anomalous \nlow-temperature state carries the characteristics of a chiral\, nematic and time-reversal-symmetry \nbreaking fluid (all of which are under most active debate currently). \nYet what crystallizes out of the current state of experimental data is a highly entangled system \nwhich is extraordinarily responsive to external perturbations. This materials main strength is \nequally its weakness\, the unusual degree of coupling between states can hinder its systematic \ninvestigation. However\, it is already clear that it provides a platform to explore strongly coupled \ncorrelated phases\, and as a result it displays a thus-far unknown electromagnetic response\, a \ndiode in which the forward direction can be switched by the application of a magnetic field. I \nwill review the current state of the field\, and discuss ongoing projects in my department. \n  \n[1] C. Guo et al.\, Nature 611\, 461-466 (2022) \n[2] X. Huang et al.\, PRB 106\, 064510 (2022) \n\n\n\n\n\n\nVenue
URL:https://www.trr360.de/event/trr360-sonderseminar-magnetic-field-versus-temperature-phase-diagram-of-an-effective-spin-1-2-zigzag-chain-in-a-magnetic-semiconductor-ybcus2-takahiro-onimaru/
LOCATION:University of Augsburg\, Room S-288 + Zoom
CATEGORIES:Sonderseminar
END:VEVENT
END:VCALENDAR