The following topics broad range to cover the most ongoing superconductivity, magnetism, and cryogenics research, which can be used to classify your abstract(s) according to its relevance to the sessions. Note that some of the topics are in the form of special focused sessions and general sessions. It is likely that your abstract will be related to more than one topic. We encourage you that during abstract submission select three topics of relevance in order of your preference, especially if you intend to have an oral presentation. Please feel any necessity, it is possible to make selections from the relevant topics in any mainstream.

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Abstract Classification Topics

Mainstream A: Superconductivity: Materials, Synthesis and Characterization
A1 A15 Superconductors from Properties to Applications
A2 Advances in Heavy Fermion Superconductivity
A3 Advances in Hydrides
A4 Advances in Nickelates
A5 Arsenides Superconductors
A6 Artificial Pinning in Superconductors
A7 Borocarbides
A8 Bulk Superconductors
A9 Carbon Based Superconductivity
A10 Fulleride Superconductors
A11 HTS Cuprates – Preformed Pairs and Intertwined Orders
A12 Wires, Tapes, and Coated Conductors
A13 HTS-Cuprates- Advances in Experiments
A14 Impurities and Defects in Superconductors
A15 Iron-Based Superconductors: Advances in Crystal Growth and Thin Films
A16 Iron-Based Superconductors: Advances in Fundamentals, Theory, and Mechanisms
A17 Iron-Based Superconductors: Experimental Properties of Materials
A18 Iron-Based Superconductors: Properties Important for Applications
A19 Kagome Superconductivity
A20 Low Dimensional Superconductivity
A21 Low-Temperature Superconductors
A22 Magnetically Ordered Iron-Based Superconductors
A23 Majorana Modes and Topological Quantum Computation
A24 MgB2: Advances in Fundamentals, Theory, and Mechanisms
A25 MgB2: Advances in Materials and Applications
A26 Nanoscale Superconductivity
A27 New Superconductors
A28 Photoemission and ARPES
A29 Proximity Induced Superconductivity in Semiconducting Nanowires
A30 PT (Parity-Time) Symmetric Supercondcting Systems
A31 Quasi One Dimensional Superconductivity
A32 Superconducting Materials Processing and Structural Properties
A33 Superconducting Single-Photon Detectors and Qubits Based on Two Dimensional Materials
A34 Superconducting Thin films and Multilayers
A35 Superconductivity in 2D Materials
A36 Superconductivity in Curved 3D Nanoarchitectures
A37 Superconductor – Insulator Transition
A38 Superconductors with Broken Spatial and Temporal Symmetry
A39 Thermal, Magnetic, and Electrical Properties of Superconductors
A40 Topological Superconductivity
A41 Tuning the Physical Properties by External Strain and Pressure
A42 Ultrathin Layered Superconductors
A43 Unconventional Superconductors and Tunable Quantum States
Mainstream B: Magnetism: Materials, Synthesis and Characterization
B1 2D van der Waals Magnets
B2 Advances in Molecular Magnetism and Applications
B3 Advances in Thin Films, Multi-Layers, and Patterned Nanostructures
B4 Advances in Nanomagnetism
B5 Carbon Based Magnetism and Graphene
B6 Cobaltates
B7 Coercivity Mechanism
B8 Dilute Magnetic Semiconductors
B9 Domain Wall Motion
B10 Electrical Field Effect on Magnetic Systems
B11 Emerging van der Waals Materials
B12 Exotic Magnetism
B13 Ferrites and Rare Earth Magnetic Materials
B14 Functional Magnetic Materials and Applications
B15 Functional Oxide Thin Films
B16 Heusler Materials
B17 Intermetallic Compounds
B18 Low Dimensional Magnetism
B19 Magnetic Skyrmions, Solitons, and Chiral Magnetism
B20 Magnetic Topological Insulators
B21 Magnetic Materials Processing and Physical Properties
B22 Magnetic Phase Transitions
B23 Magnetic Recording, Sensors and Microwave Devices
B24 Magnetic Shape Memory Alloys and Magnetocalorics
B25 Magnetism in Correlated Electron Systems
B26 Magnetism of Nanoparticles, Nanowires, and Nanostructures
B27 Magnetism and Spin Effects in Graphenes
B28 Magnetization Dynamics and Resonance
B29 Magnetophotonics
B30 Magnetoresistance and Spin Effects
B31 Magnetostructural Transitions and Related Effects
B32 Manganites
B33 Micromagnetics
B34 Molecular Spintronics Based on Coordination Compounds
B35 Molecular Magnetism
B36 Multiferroics and Magnetic Oxides
B37 Nanomagnetism in Biological and Bio-inspired Systems
B38 Novel Developments in Orbital Physics
B39 Novel Functional Magnetic Materials: Basic Approach and Applications
B40 Permanent Magnets: Materials and Their Applications
B41 Recent Trends of Materials in Low-Dimensional Magnetism
B42 Self-Organization and Transport in Bio-Inspired Active Magnetic Colloids
B43 Shape Memory Alloys and Magnetocalorics
B44 Shapeable Magneto-Electronics
B45 Soft and Hard Magnetic Materials
B46 Spin Glasses and Spin Ice
B47 Spin Torque Materials
B48 Spin Mechanics
B49 Spintronics – Semiconductors, Oxide Interfaces, Graphene, and Topological Insulators
B50 Spintronics – Spin Hall Effect, Spin Caloritronics, and Other Spin-Transport Effects
B51 Spintronics – Devices and Applications
B52 Spintronics – Other Aspects
B53 Spintronics – Spin Transfer Torque
B54 Studies of the Low-Dimensional Frustrated Magnets
B55 Topological Heterostructures and Devices
B56 Topological Spintronics
B57 Ultrafast Magnetization Dynamics and Switching
B58 Van der Waals Kitaev Materials
Mainstream C: Interplay of Superconductivity and Magnetism
C1 Advances in Complex Oxide Materials
C2 Coexistence of Superconductivity and Magnetism-Detection, Control and Application
C3 Magnetic Superconductors and Triplet Superconductivity
C4 Magnetic Vortex Dynamics
C5 Multicomponent/Multiband/Multigap Superconductivity
C6 Nanotechnology for Superconductivity
C7 Non-Hermitian Quantum Mechanics and Nonequilibrium Phase Transitions in Magnetic and Superconducting Systems
C8 Ruthenates
C9 Skyrmionic/Superconducting Heterostructures Systems
C10 Superconducting Spintronics
C11 Superconductivity and Magnetism at Nanoscale
C12 Superconductivity and Magnetism in Perovskite Oxides
C13 The Interplay of Magnetism and Superconductivity
C14 The Coexistence of Superconductivity and Magnetism
C15 Transition Metal Oxides
C16 Vortex Matter: Fundamental Properties and Simulations
C17 Vortex Dynamics in Superconductors
C18 Vortices in Superconductors/Ferromagnetic Hybrids
C19 Vortices and Nano-Structured Superconductors
Mainstream D: Large Scale and Energy Applications of Superconducting and Magnetic Materials
D1 AC Losses in Superconductors
D2 Boron Based Permanent Magnets & Magnetic Materials for Applications
D3 Superconducting Flux Pumps
D4 Large Scale Applications of Superconductors and Their Fundamental Technologies
D5 Large Scale Applications of Superconductors: Accelerators, Fusion and ITER
D6 Magnet Science and Technology
D7 Magnetic Imaging and Microscopy (E.G. MOKE, SNOM, MFM Etc.)
D8 Medical, Scientific and Energy Applications of Magnetic Materials
D9 Medical, Scientific and Energy Applications of Superconductors
D10 Power Applications of Superconductors
D11 Power Cables
D12 Recent Progresses in Renewable Energy Technology Implications-Materials Perspectives
D13 Superconducting Motors
D14 Superconducting Magnets for the 100 TeV Hadron Future Circular Collider
D15 Superconductor Fault Current Limiters: Principles and Practice
D16 Techniques and Instrumentation of Large Scale and Energy Applications
D17 Thermoelectric Measurements and Characterizations
Mainstream E: Electronic Applications of Superconducting and Magnetic Materials
E1 Advances in SQUID Technology
E2 Applications of CPP-GMR Devices
E3 Bio-magnetism and Medical Applications
E4 Digital/Mixed Signal Superconducting Circuits and Systems
E5 Hybrid Superconducting Devices
E6 Josephson Junctions and SQUIDS
E7 Magnetic Nanoresonators
E8 Microwave Devices
E9 RF and Microwave Devices and Applications
E10 Superconducting Circuits and Systems
E11 Superconducting Detectors and Readout
E12 Superconducting Devices Materials and Fabrication
E13 Techniques and Instrumentation for Electronics Applications
E14 Terahertz Applications
E15 Terahertz Emission and Intrinsic Josephson Junctions
Mainstream F: Theory, Mechanisms and Fundamentals
F1 Ab Initio Magnetism
F2 Frustrated Magnetism and Spin Systems
F3 Topological Kondo Physics and Systems
F4 Lattice and Isotope Effects in Layered Superconductors
F5 Mott Transition / Vortex Physics
F6 Non-Equilibrium Superconductivity
F7 Novel Phenomena in Type-I Superconductivity
F8 Numerical Modelling of Superconducting Materials and Applications
F9 Phase Diagram of Superconductors, Pseudo-Gap and Order Parameters
F10 Proximity Effects in Superconductors
F11 Spin-Dependent Proximity Effect
F12 Spin Dynamics of Correlated Systems
F13 Strongly Correlated Electrons/Systems
F14 Study of Fermi Surface of HTS by Magnetic Quantum Oscillations
F15 Superconducting Fluctuations and Related Effects
F16 Theory of Magnetism
F17 Theory of Superconductivity
F18 Time-Reversal Symmetry Breaking in Unconventional Superconductors
F19 Topological Insulators and Superconductors
F20 Valance Fluctuations
Mainstream G: Cryogenics, Materials and Engineering
G1 Cryogenic Engineering Modeling
G2 Cryogenic Materials, Engineering, and Applications
G3 Cryogenic Power Cables and Leads
G4 Cryogenics – Cryocoolers
G5 Cryogenics – Electronics
G6 Cryogenics – Large Facility and Testing
G7 Cryogenics – Refrigeration, and Liquefaction
G8 Hydrogen Cryomagnetics
G9 Innovative Cooling Systems
G10 Instrumentation
G11 Low-temperature detectors
G12 Materials Testing and Evaluation
G13 Thermodynamics at Cryogenic Temperatures
G14 Thermometry
Mainstream H: Quantum Sciences and Technologies
H1 Bose-Einstein Condensation and Superfluidity
H2 Cavity Quantum Electrodynamics
H3 Coherence and Decoherence in Qubits
H4 Colossal Magnetoresistance
H5 Correlated Topological Matter
H6 Correlations in Artificial Quantum Structures
H7 Dirac Semimetals and Weyl Semimetals
H8 Entanglement Related Phenomena in Quantum Mechanics
H9 Fault-Tolerant Levels in Single-Qubit Fidelities
H10 Fractional Quantum Hall Effect
H11 Graphene and Other 2D Materials-Theory
H12 Graphene: Advances in Experimental Studies
H13 Graphene-Related Research: Properties Important for Applications
H14 Machine Learning Based on Experimental Data
H15 Machine Learning-Based  on DFT Simulations of Quantum Materials
H16 Magnetism and Spin Effects in Low-Dimensional Materials
H17 Magnetism in Quantum Materials
H18 Magnetization Dynamics and Magnonics
H19 Many-Body Phenomena
H20 Mott Insulators
H21 Nano-Electromechanical Systems
H22 Non-Equilibrium Phenomena in Quantum Materials
H23 Photonic Qubits
H24 Quantum Algorithms
H25 Quantum Computation
H26 Quantum Criticality and Related Phenomena
H27 Quantum Criticality and Spin Liquids
H28 Quantum-Dot (GaAs and Si) Qubits
H29 Quantum Error-Correction and Fault-Tolerance
H30 Quantum Hall Effect
H31 Quantum Information Technology
H32 Quantum Magnonics
H33 Quantum Materials for Topological Devices Based on Majorana Modes
H34 Quantum Phenomena
H35 Quantum Spin Liquids
H36 Quantum Technologies Based on 2D Oxides
H37 Quantum Transport
H38 Semiconductor Qubits
H39 Semiconductor-Superconductor Hybrid Circuits-QED
H40 Single-Atomic Qubits
H41 Solid-State Qubits
H42 Spin Qubits
H43 Superconductor Qubits
H44 Topological Insulators
H45 Topological Superfluid
H46 Topological Quantum Computation
H47 Topological Quantum States
H48 Topological Quantum Matter
H49 Trapped Ions Based Qubits
H50 Ultracold Atoms and Related Systems
Other Related Topics of Interest: Miscellaneous 
O1 Miscellaneous
O2 Other Related Aspects of Cryogenics and Materials
O3 Other Related Aspects of Magnetism and Magnetic Materials
O4 Other Related Aspects of Superconductivity and Superconducting Materials
O5 Other Related Aspects of Quantum Sciences and Technologies