Track Categories

The track category is the heading under which your abstract will be reviewed and later published in the conference printed matters if accepted. During the submission process, you will be asked to select one track category for your abstract.

The first is the Special Theory of Relativity, which deals essentially with whether rest and movement are relative or absolute and the consequences of Einstein's conjecture that they are relative.The second is the General Theory of Relativity, which mainly accelerates particles, mainly due to gravity, and acts as a radical revision of Newton's theory, predicting significant new results for fast-moving or very massive bodies. The General Theory of Relativity correctly reproduces all the valid predictions of Newton's theory but extends his understanding of some of the basic principles. Newton’s physics had previously assumed that gravity operated through empty space, but theory had no explanatory power in how the distance and mass of a given object could be transmitted through space. General relativity shapes this paradox because it shows that objects continue to move in a straight line over time, but we observe movement as an acceleration due to the curved nature of space.

Nanoscience and Nanotechnology are the disciplines that study systems and manipulate matter at the atomic molecular, and super molecular scales (the nanometric scale). At such a length scale, quantum mechanical and surface boundary effects become relative, giving properties to materials not observed at larger macroscopic scales.

 

The field of physics that studies multi-body systems in the concentrated phase of matter, namely liquids (including quantum liquids) and solids (including crystallography and magnetism). The methods used include experiments, theories and numerical simulations. Concentrate physics applies ideas in quantum mechanics, quantum field theory and statistical engineering and overlaps material science, nanotechnology and chemistry.

The dynamics of liquids is the study of the movement of liquids, gases and creatures. The flow depends on the intrinsic properties of the material itself, such as compressibility, viscosity and density. Examples of systems are the fluid flowing through a conduit or capillary, the air moving in a plane of the plane and the movement of the plasma in a magnetic field of stars.

Quantum optics is the study of how individual light puppets, known as photons, interact with atoms and molecules. This includes studying the particle properties of photons. Photons have been used to test many of the anti-intuitive predictions of quantum mechanics, such as entanglement and teleportation, and are a useful resource for processing quantum information.

 

Biophysics is the study of natural phenomena and physical processes in living things, on scales that cover molecules, cells, tissues and organisms. Biophysics uses the principles and methods of physics to understand biological systems. It is an interdisciplinary science, closely linked to quantitative and systems biology.

Medical physics is a very established area where progress is usually technical. However, physicists from other fields of physics can make unexpected contributions. New ideas, technology transfer and interdisciplinary cooperation can lead to exciting developments. the application of physical concepts, theories and methods in medicine or healthcare. This collection brings together various news, review and opinion articles highlighting and discussing such trends.

 

Plasma physics is the study of a state of matter involving charged particles. Creatures are usually created by heating a gas until the electrons are disconnected from their parent atom or molecule. This so-called ionization can also be achieved using high-power laser light or microwaves. Creatures are naturally found in stars and in space.

 

Accelerator physics, the study of how these machines are designed, manufactured, and operated, is a field rich in non-linear dynamics, computational physics, engineering and materials sciences. We cover the physics of charged particle beams subjected to magnetic guidance and focusing systems, the radio frequency acceleration system and large number of different sensors for diagnosing the beam state and various actuators for controlling it.

 

Atomic force microscopy (AFM), a form of scanning probe microscopy, is a technique where a cantilever with a sharp tip is systematically scanned across a sample (biological or material) surface to produce a nanometre-resolution topographic map. AFM can also be used to measure forces between the tip and sample.

Molecular imaging involves a variety of imaging techniques based on the use of exogenously added probes to target and detect the desired cellular or molecular processes in a living organism.

 

Nuclear astrophysics is the study of nuclear-level processes that occur naturally in space. Notably, this includes understanding the chain of fusion events, or nucleosynthesis, that occurs in stars, and how this can be detected from a distance by measuring the radiation these processes produce.

 

This will serve as an introduction to the field of astrodynamics, especially from a practical, mechanical perspective. We will focus on anthropogenic satellites and the dynamics of the orbit around satellites around the earth, the moon and other "local" objects. We will look at practical applications, such as Earth's orbits, lunar and interplanetary orbits, ballistic missiles and interstellar escape routes.

Ballistics is the field of engineering that deals with launch, flight behaviour and missile impacts, special ammunition such as bullets, unexploded ordnance, rockets or the like. the science or art of projecting and accelerating missiles to achieve the desired performance

The physics of space is the study of the natural phenomenon that occurs in our solar system. Specifically, the sun, the particles and the radiation they create and how they affect the planets. This includes solar wind and its interaction with the Earth and the near-Earth space is called space weather.

 

Computational physics can be broadly defined as "the science of using computers to solve physical problems and further physical research." Large scale studies of quantum mechanics in nuclear, atomic, molecular and concentrated physics.

Control theory, a field of applied mathematics related to the control of certain physical processes and systems. Although the theory of control has deep connections with classical areas of mathematics, such as the calculation of variants and the theory of differential equations.

Electronics that work with digital signals. In contrast, analog circuits handle analog signals whose performance is more dependent on the manufacturing tolerance, signal attenuation and noise. Digital techniques are useful because it is much easier to obtain an electronic device to navigate one of the many known situations than to accurately represent a continuous range of values.

Engineering physics is study of the combined fields of physics, mathematics and engineering, in computers, nuclear, electrical, electronics, materials or engineering. Emphasizing on the scientific method as a rigorous basis, it seeks ways to implement, design and develop new solutions in engineering. Most programs integrate an applied physics with a specialized engineering major, such as mechanical, computer or aerospace 

Geophysics is, as a rule, a study of the physics of planetary bodies and atmospheres, including the flow of energy through these systems. The term can also be used more narrowly to describe the study and characterization of the Earth's interior using non-invasive methods such as seismic images.

 

Applied physics is the study of physics for a practical purpose, as opposed to physics, whose sole purpose is an improved fundamental understanding. This includes technological developments such as the development of electronics, photonics and device physics or the improvement of practical research, such as experimental nuclear physics and experimental particle physics.

Laser material processing uses high beam light in the fabrication of materials. This may include cutting, etching, drilling, or welding metals. It may also include laser cleaning materials. The health and safety issues associated with the use of these techniques are an important element. Total internal reflection prevents light inserted   into one end of the fibre from escaping through the sides. Transferring information optically in this way enables much higher transmission rates than using an electrical signal.