The Search for Large Extra Dimensions using Dijet Production from pp Collisions at 1.8 TeV

Searching for large additional size digests using Dijet generation with 8 TeV pp conflicts is a very interesting topic for additional size search and has been studied using various analysis methods and methods. [1, 2, 3, 4] Determining the presence of too large (LED) as large (oversized or higher) gravity and its gravity (gravity (spin 2)) can access these additional dimension flows Can shape Atwood has created a cross section of the model using the hadron collider and 2 T 2 hadron die jet process. [2] Using this model, we recommend using Ms, Planck energy levels to determine optimum and establish boundaries.

2018 is the last year ATLAS used data as part of the operation of Large Hadron Collider 2. During this period, proton-proton collisions of 13 TeV produced about 30 times Higgs bosons of the 2012 Higgs Boson. As a result, more and more results are used to study Higgs particles in more detail. Over the next few years, analysis of large Run 2 datasets is not only an opportunity to achieve new levels of precision in previous measurements, but also predicts the existence and testing of new physical conditions with the proposed standard model It is also a new way. In a way independent of model as much as possible. The accuracy of this new level depends on a better understanding of detector performance, as well as simulation and algorithms for identifying particles passing through it. It also provides new theorists with new challenges to keep pace with improving the accuracy of the experiment.

In 1984, some physicists and engineers at the European Atomic Energy Research Center were seeking the possibility to install a proton-proton accelerator with a very high collision energy of 10 - 20 TeV in the same tunnel as LEP. If the light intensity is very high, this accelerator detects the whole possible mass range of Higgs. But this high brightness means that any interesting crash involves dozens of background clashes. Considering the current state of detector technology at that time, this seems to be a very difficult task. CERN wisely began a powerful research and development program to enable the detector to make rapid progress. This enabled early cooperation, later ATLAS, CMS and other LHC experiments.

As early as 2008, the large hadron collider (LHC), which is operated by the European Atomic Energy Research Organization (CERN), was accused of manufacturing a small black hole and physicists were able to detect further dimensions It was. For many people, this seems to be a miserable science fiction movie. It is not surprising that when two people filed a lawsuit to block the operation of LHC it creates a black hole destroying the world. However, the physicists believe that thought was ridiculous and the lawsuit was dismissed.