Current opinion

, Volume: 10( 4) DOI: 10.37532/2320-6756.2022.10(4).274

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Advance Knowledge in Physics and Applied Science

*Correspondence:

John Orwell
Executive Manager, Journal of Physics and Astronomy, UK
E-mail: physics.astronomy@aol.com

Abstract

It provides a premier technical forum for expressing knowledge about the advanced research and developments, as well as exploration of new applications, and technologies and to explore new trends in the fields of Physics, Mathematics and Science.

Keywords

Physics; Technologies; Condensed matter physics

Introduction

Experts in Condensed Matter Physics, leaders from the fields of Materials Physics, Mathematics, and students from diverse groups, leading universities, research institutions, and Physics Industries will share their research experiences on all aspects of this rapidly expanding field at the "Advances in Physics, Mathematics, and Applied Science" Budapest, Hungary, which includes prompt Keynote presentations, Oral talks, and Exhibitions from experts in Condensed Matter Physics, leaders from the fields of Materials Physics, Mathematics, and students from diverse groups, leading universities.

Materials Science and Engineering

The interdisciplinary field of substances technology, often known as substances technology and engineering, is concerned with the design and development of new substances, particularly solids. The Enlightenment gave rise to the intellectual beginnings of substances technology, when scholars began to use analytical reasoning from chemistry, physics, and engineering to comprehend ancient, phenomenological observations in metallurgy and mineralogy. Physicists, chemists, and engineers are all involved in materials technology. As a result, the field has long been considered a sub-discipline of those related fields by educational institutions. Substances technology became more widely recognised as a distinct and important area of technology and engineering in the 1940s, and major technical universities throughout the world established dedicated colleges for its study.

Bio-Physics and New Dimension in Technology

Biophysics is an interdisciplinary science that investigates organic systems using physics methodologies. Biophysics is concerned with organic organisation at all scales. Biophysics has a lot in common with biochemistry, physical chemistry, nanotechnology, bioengineering, computational biology, and biomechanics.

Materials Physics

The term "material physics" is used to describe the physical properties of substances. It is a combination of physical sciences, strong mechanics, strong kingdom physics, and substance science. Materials physics is a subclass of condensed count physics that applies fundamental condensed count theories to sophisticated multiphase media containing technologically important chemicals.

Modern Physics

Modern physics is a branch of physics that developed in the early twentieth century and onward, or branches that were heavily influenced by early twentieth-century physics. Quantum mechanics, special relativity, and general relativity are all important branches of modern physics.

Applied Physics

Applied physics is the software of physics to remedy medical or engineering problems. It is commonly taken into consideration to be a bridge or a connection among physics and engineering. "Applied" is prominent from "pure" through a diffused mixture of factors, along with the incentive and mind-set of researchers and the character of the connection to the era or technology that can be laid low with the work. Applied physics is rooted with inside the essential truths and primary standards of the bodily sciences, however is worried with the usage of medical ideas in sensible gadgets and systems, and with inside the software of physics in different regions of technology.

High Energy Nuclear Physics

High-electricity Nuclear physics studies nuclear reactions in high-voltage regimes. The study of heavy-ion collisions in different particle accelerators in comparison to lighter atoms is the subject's main focus. Those types of collisions are theorised to produce quark–gluon plasma at high enough collision energies. Because electron–positron colliders have lesser luminosities, one expects to find information about the electromagnetic manufacturing of leptons and mesons in peripheral nuclear collisions at high energies.