Themes and Topics

I.1.    Unconventional superconductivity and magnetism in SCES

I.2.   Topological states in SCES, including Dirac and Weyl semimetals

I.3.   Heavy fermion systems, Kondo physics, and valence fluctuations including actinides

I.4.   Frustration and quantum spin liquids

I.5.   Crystal electric field (CEF) effects and multipolar ordering in SCES

I.6.   Quantum phase transitions and related phenomena including metal-insulator transitions

I.7.    Non-equilibrium physics in SCES, including mesoscopic Kondo and non-equilibrium pump-probe states

I.8.   Theoretical frameworks, numerical methods, and AI-assisted approaches for strong correlations

I.9.   Materials design and novel advanced materials

I.10. Fermi surfaces and electronic structure of correlated phases

II.1.    Hard magnetic materials

II.2.   Soft magnetic, amorphous, and nanocrytalline materials

II.3.   Materials for energy applications

II.4.   Emerging properties in functional magnetic materials

II.5.   Multiferroics and magnetoelectric materials

II.6.   Magnetic shape memories and magnetoelastic materials

II.7.    Critical challenges and magnetic materials (raw materials, sustainability, automotive)

II.8.    Magnetophotonics and magnetoplasmonics

II.9.    Magnetic topological and magneto-chiral materials

II.10. Altermagnetic materials

III.1.      Advanced synthesis of magnetic thin films and nanostructures

III.2.      Anisotropy effects in magnetic thin films and multilayers

III.3.      Surface and interface effects, exchange bias and exchange springs

III.4.      Multifunctional and strongly coupled phenomena in confined magnetic systems

III.5.      Magnetic nanoparticles and nanowires

III.6.      Theory, modeling and simulation of nanomagnetic systems

III.7.       Low-dimensional magnetism and van der Waals magnets

III.8.      Non-collinear spin textures and emergent phenomena in confined systems

III.9.      Magnetism in 3D nano-architectures

IV.1. Spin transport, spin tunneling, spin torque and caloritronics phenomena

IV.2.  Spin-orbit effects, orbitronics, and electric field effects on magnetic systems

IV.3.  Anisotropy effects in magnetic thin films and multilayers

IV.4.  Molecular spintronics and chiral spintronics

IV.5.  Altermagnetism, unconventional magnetism, and antiferromagnetic spintronics

IV.6.  Magnetic textures, 3D nanomagnetism, and micromagnetics

IV.7.   Magnonics, including magnon-X couplings

IV.8.  Quantum spintronics, including coherent spin manipulation in semiconductors and superconductors

IV.9.  Fundamentals of spin-based computing

IV.10. Ultrafast magnetization dynamics including terahertz spintronics

V.1.  Magnetic sensors

V.2.  Magnetic devices for information storage

V.3.  Applications of magnonics and spin textures for information technologies

V.4.  Unconventional computing with magnetic systems

V.5.  Spin-based quantum computing and sensing

V.6.  Flexible spintronics and magnetic micro-electro-mechanical systems (MEMS)

V.7.   Novel tools for investigating magnetism at the nanoscale

V.8. Emerging techniques at large facilities (neutron, synchrotron, high fields, etc.)

V.9.  Biomedical, food, and environmental applications

V.10. Interdisciplinary applications and technologies