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 |