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Scientific Program
8th International Conference on Quantum Physics and Mechanics, will be organized around the theme “”
Quantum Mechanics 2023 is comprised of 15 tracks and 0 sessions designed to offer comprehensive sessions that address current issues in Quantum Mechanics 2023.
Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.
Register now for the conference by choosing an appropriate package suitable to you.
The quantum imaging session bring you the latest research on limits of classical optics overcome by quantum technology. An example of quantum imaging results is the quantum laser pointer, which demonstrates the possibility of improving the measurement of position of centre of a light beam at beyond the short noise limit. Recent research works are focused on the experimental and application to improve quality of quantum imaging process will also be discussed in our quantum physics conference.
- Track 1-1Image Processing
- Track 1-2Optical Data Storage and Optical Measurements
- Track 1-3Nonlocal Quantum Imaging Physics
- Track 1-4Quantum Ghost Imaging
- Track 1-5Quantum Concepts in Electron Microscopy
- Track 1-6Recent Developments in Quantum Imaging
- Track 1-7Quantum Imaging and Future Directions
- Track 1-8Ultrafast TEM-Time Shaping
- Track 1-9Light-Electron Interaction
- Track 1-10Electron Phase Plates and Beam Shaping
- Track 1-11Total Cost of Ownership Reduction for Powered Respiratory Protection in Nuclear Facilities
- Track 1-12Pipes and Valves
- Track 1-13Condition Monitoring and Inspection
The core topic that will be covered in AMO physics in our quantum physics conference includes research in atomic and molecular properties of matter. In this quantum physics conference lays a platform for researchers to present their research and form a network with the peers in their respective fields. Applications of AMO physics in different technologies such as fibre optics, fusion reactors, quantum computers, lasers and materials science will be covered in this session.
- Track 2-1Collisions involving Antimatter, Clusters and Surfaces
- Track 2-2Atom-atom and Atom-Molecule collisions
- Track 2-3Electron-Atom collisions
- Track 2-4Electron-Atom collisions
- Track 2-5Electron-Molecule Collisions
- Track 2-6Ion-atom and Ion-Ion Collisions
- Track 2-7Recent Developments in Electron-atom Collisions
Quantum Physics session brings you the research on the theoretical, experimental and applied quantum physics phenomena. The prediction of behaviour of particles at the subatomic level where the classical mechanics is unreliable. An example of a system that exhibits quantum physical effects on macroscopic scale is super fluidity. This quantum physics theory also provides probability and descriptions for previously poorly understood phenomena.
- Track 3-1Theoretical Quantum Physics
- Track 3-2Quantum Nano Science and Nano Physics
- Track 3-3Quantum Imaging
- Track 3-4Quantum Safe-Security
- Track 3-5Quantum electronic device Engineering
- Track 3-6Quantum Genome Sequence
- Track 3-7Quantum communication
- Track 3-8Quantum Software Research
- Track 3-9Quantum Gravity & Cosmology
- Track 3-10Quantum Machine Learning & AI
- Track 3-11Quantum Artificial Intelligence
- Track 3-12Quantum Information
- Track 3-13Quantum Optics and Photonics
- Track 3-14Classical Machine Learning
- Track 3-15Quantum Algorithms
- Track 3-16Quantum Architect
- Track 3-17Quantum Engineering
- Track 3-18Quantum Sensing
Nuclear Engineering is the branch of engineering concerned with the application of breaking down atomic nuclei (fission) or of combining atomic nuclei (fusion), or with the application of other sub-atomic processes based on the principles of nuclear physics..
- Track 4-1Operating Plant Experience
- Track 4-2Nuclear Fuel and Engineering
- Track 4-3Nuclear Plant Engineering
- Track 4-4SMR and Advanced Reactors
- Track 4-5Nuclear Safety, Security, and Cyber Security
- Track 4-6Codes and Standards
- Track 4-7Robotics
- Track 4-8Thermal-Hydraulics
- Track 4-9Computational Fluid Dynamics (CFD)
- Track 4-10Verification and Validation
- Track 4-11Decontamination & Decommissioning
- Track 4-12Beyond Design Basis
- Track 4-13Nuclear Policy
- Track 4-14Probabilistic Risk Assessments
- Track 4-15Nuclear Radiation
This conference focuses on the special needs of the nuclear and fossil power plant simulation community and includes presentations by technology and industry leaders, technical sessions, panel and roundtable discussions, and vendor exhibits. The primary goal of the conference is to promote open exchange of simulator related information between all attendees.
- Track 5-1Simulator Modifications
- Track 5-2Simulator Upgrades
- Track 5-3Virtual Simulator Technology
- Track 5-4Knowledge Retention/Succession Planning
- Track 5-5Non-Training Uses of Power Plant Simulators
- Track 5-6Emulated Stimulator Technology
- Track 5-7Life Cycle Management of Simulator Components
- Track 5-8Simulator Oversight & Management
- Track 5-9Regulations
- Track 5-10Hardware Upgrades
- Track 5-11Glass Panel Simulator Usage
- Track 5-12Glass Panel Simulator Usage
- Track 5-13Simulator Support Systems (Audio/Video/UPS/HVAC, etc.)
- Track 5-14Steam Generators
- Track 5-15Fuel Technology/Firing Systems
Conventional power plants will be indispensable in maintaining secure energy supplies also in the coming decades. In that context, the focus in the past was increased efficiency and reduced emissions thanks to state of the art plant technology. In times of an increasing share of volatile renewable generation the issue of flexibility of conventional power plants is of growing importance. The fundamental challenge for operation of the power plants is competition, with its market-driven rules.
- Track 6-1Civil Concepts/Specific Civil Solutions
- Track 6-2Instrumentation and Control
- Track 6-3Civil Structural Maintenance / Condition Monitoring
- Track 6-4Cooling Systems in Power Plants
- Track 6-5Gas Turbines
- Track 6-6Supervision of Construction and Assembly/Quality Assurance
- Track 6-7Power Generation Maintenance Optimization Network (PGMON)
- Track 6-8Materials and Quality Assurance
- Track 6-9Acceptance and Control Tests
- Track 6-10Fluidized Bed Firing Systems
- Track 6-11Reference Designation and Plant Documentation
- Track 6-12Plant Management Systems and Technical IT
- Track 6-13Electrical Engineering and I&C
- Track 6-14Steam Turbines
- Track 6-15Electrical Equipment
- Track 6-16Flue Gas Cleaning Systems
- Track 6-17Industrial and Co-generation Stations
- Track 6-18Thermal Waste Utilization
The opposite of a nuclear explosion, nuclear reactors are the controlled release of fission energy. They serve the purpose of converting “nuclear energy” to heat. The fuel elements contain the fissile material, typically uranium or plutonium, which is used as the fuel to undergo fission and provide the nuclear energy.
- Track 7-1Secondary water chemistry
- Track 7-2Primary water chemistry & radio-chemistry
- Track 7-3Maintenance & long term operation
- Track 7-4Monitoring updates & new developments
- Track 7-5Auxiliary systems water chemistry & waste treatment
- Track 7-6Advanced reactors
- Track 7-7Numerical & simulation tools
There are several types of quantum computers (also known as quantum computing systems), including the quantum circuit model, quantum Turing machine, adiabatic quantum computer, one-way quantum computer, and various quantum cellular automata.
- Track 8-1Computational Quantum Physics
- Track 8-2Quantum information and computation
- Track 8-3Quantum Computing Hardware Engineering
- Track 8-4Cloud Computing
- Track 8-5Quantum Computing
- Track 8-6Superposition
The two day event will bring together senior executives from the key industry stakeholders from Energy Providers, Plant Owners & Operators, Industry Consultants & Experts, Lawyers, Purchasing and Procurement Management Professionals, Nuclear Regulators, Nuclear Technology Companies, Industry Investors, Asset Management Companies, Nuclear Engineers and Safety Inspectors, Decommissioning Managers, Waste Management Companies, Governmental representatives, Radiation and health protection agencies, Packaging & Transportation Officials, Academic Institutions, Research Organizations and Market Analysts.
- Track 9-1Overview on the Status of nuclear Decommissioning
- Track 9-2 Retaining Competency for Safe Transports of Radioactive Waste in Future
- Track 9-3Regulatory Challenges and Opportunities in Decommissioning and Waste Management
- Track 9-4Decommissioning Project Management
- Track 9-5Transition from Operation to Decommission
- Track 9-6Analyzing New Forms of Contract Models
- Track 9-7Investigating Technical Solutions
Quantum Mechanics or Quantum Physics session brings you the research on the theoretical, experimental and applied quantum physics phenomena. The prediction of behaviour of particles at the subatomic level where the classical mechanics is unreliable. An example of a system that exhibits quantum physical effects on macroscopic scale is super fluidity. This quantum physics theory also provides probability and descriptions for previously poorly understood phenomena.
- Track 10-1Interpretation of Quantum Mechanics
- Track 10-2Quantum Error Correction
- Track 10-3Block chain Technology
- Track 10-4Quantum Metrology and Sensing
- Track 10-5Quantum Logic and Simulation
- Track 10-6Quantum Transport and Dissipation
- Track 10-7Quantum Plasmonics
- Track 10-8Quantum Cryptography
- Track 10-9Quantum Information Science
- Track 10-10Quantum States and Quantum Dots
- Track 10-11Quantum Thermodynamics
- Track 10-12Quantum Information Theory
- Track 10-13Molecular Quantum Mechanics
- Track 10-14Applications of Quantum mechanics
- Track 10-15Quantum technology and Measurement
- Track 10-16Interpretation of Quantum Mechanics
- Track 10-17Quantum interference
- Track 10-18Applied Mathematics
- Track 10-19Quantum chromo dynamics
- Track 10-20Quantum Electronics
- Track 10-21Quantum Materials
- Track 10-22Pure and Applied Physics
- Track 10-23Laser, Optics & Photonics
The quantum field theory session deals with the theoretical frameworks underlying the classical theories and reproducing particles that do not exist in quantum physics. Statistical application of condensed matter physics, quantum gravity and quantum electrodynamics (QED) are the core theories of focus in this quantum field theory session. Research in quantum physics is substantial in the past decade, and it continues to be an area of interest to many theoretical physicists who try to apply mathematical solutions to the quantum particles
- Track 11-1Quantization of the Bosonic String
- Track 11-2Conformal Field Theory
- Track 11-3Quantum Decoherence and Dephasing
- Track 11-4Bosonic String Action
- Track 11-5Quantization of Non Abelian Gauge Theories
- Track 11-6Quantum Decoherence and Dephasing
- Track 11-7Radial Quantization
- Track 11-8Quantum Brownian Motion
- Track 11-9Quantum Chromodynamics
In 2016, three physicists were awarded Nobel Prize for rewriting our understanding of exotic phase transitional quantum states on the surfaces of materials. This quantum physics conference gathers scientists working on the interactions between theoretical representation and low-dimensional topology. The key focus of this session will be on the quantum physics interaction between low-dimensional topology such as invariants, topological quantum filed theory, categorification and more.
- Track 12-1 Quantum Invariants
- Track 12-2Khovanov and Heegaard Floer Homology
- Track 12-3Hyperbolic Geometry
- Track 12-4Volume and AJ Conjectures
- Track 12-5Topological Insulators and Graphene
- Track 12-6Chern-Simons Theory
- Track 12-7Topological Matter
- Track 12-8Quantum Transport
The challenges in quantum spintronics will be focused and this quantum physics conference brings together the quantum physicists at the forefront to advance this key area that enables innovation. A recent research shows that the quantum particle interaction can be on and off inside a quantum system, which potentially paves way for many spintronic applications. Innovative research in electronics and data storage devices is some areas of interest in this session.
- Track 13-1Spin-Dependent Optical
- Track 13-2Spin Coherence and Manipulation
- Track 13-3Spin-Dependent Thermal
- Track 13-4Spintronic Materials
Every technology around the world from smart phones to space satellites have to be ready change to quantum physics in the future. With the development of science and technology, quantum technology is a key factor to the applications of quantum computers, quantum cryptography and quantum optics. The quantum technologies, with its radically different concepts pose a land of opportunities and challenges, with researchers actively working to overcome using quantum physics.
- Track 14-1Quantum Simulators
- Track 14-2Quantum Science
- Track 14-3Quantum Networks and their Applications
- Track 14-4Quantum Sensors
- Track 14-5Quantum Sensors
- Track 14-6Quantum Information
- Track 14-7Quantum Communication
- Track 14-8Quantum Metrology
- Track 14-9Quantum Light-Matter Interfaces
Quantum sensors have the potential to transform the world like never before. The quantum sensing session explores the peculiarities of quantum system to develop new and improved sensors. The potential for quantum sensor application in the world are unlimited, right from detecting the tiny impulses in the body to identifying a possible earthquake or volcanic eruption, the quantum sensors offers an advantage over the conventional classical mechanics with much precision and accuracy. Here in this quantum physics conference, researchers will discuss the most imminent research highlights.
- Track 15-1Mesoscopic Device Processing
- Track 15-2Quantum Sensors
- Track 15-3Quantum Detection and Sensing
- Track 15-4Optical Quantum Sensors
- Track 15-5Quantum Lithography