High Energy Physics

I was able to answer profound questions such as the origin of the substance, the superiority of the substance in the anti-substance, the strong motivation to clarify the secret of our universe, so I got a doctoral degree and then I got my physics career It began to pursue. As a candidate for doctoral degree, I would like to understand and contribute to a very attractive field of high energy physics. I first worked in high school and participated in the Global Mathematical Science Olympics held at the University of Canberra.

The work of the second author (HPS) is supported by the High Energy Nuclear Physics Director of the Department of Energy's Department of Energy's High Energy Physics Section under the contract DE-AC 03-76 SF 00098. . The work of the third author (M. B.) was supported by Quebec Santiago (FRSQ) scholarship. We appreciate Joseph O'Neill for insight into the preliminary version of our manuscript. This research is based on Copenhagen interpretation of quantum theory and extension of von Neumann. Copenhagen's interpretation is basically taught in standard quantum physics courses and used for practical practice. This interpretation makes it possible for human agents to enter mechanics at an important moment, that is to say "basic" problems, ie to propose specific physical problems. This item "free" selected by the agent is the basis of current work.

We need to explain the term high energy physics in detail. Intuitively, it seems that the physical combination of 'high energy' and very small low quality objects (elementary particles etc.) is incorrect. In contrast, an example of a macroscopic system, 1 gram of hydrogen has a mass of about 6 × 1023 times the mass of a single proton. Even the entire proton beam circulating in the large hasronic collider contains up to 3.23 × 10 14 protons with energy of 3.2 × 10 14 eV each and the total beam energy is at most about 2.1 × 1027 eV or about 336.4 It is MJ. It is 2.7 x 105 times lower than the mass energy of 1 gram of hydrogen. However, the macroscopic field is "low energy physics" and the quantum particles are "high energy physics".

Many of the skills necessary to build a spacecraft include high energy physics and materials technology that can determine the lifespan of a mission to withstand the demands of high energy physical processes without decades I will. High energy physics requires large and expensive machines. And it is a machine that can be called "big science". Big science is the largest scientific project organization and investment in a mature industrialized society, at that time scholars, private companies, government agencies concentrated on such large-scale scientific projects with long execution times, expensive countries We gathered resources. We will conduct scientific research on the size of the large hadron collider and ITER.