Some of the material in is restricted to members of the community. By logging in, you may be able to gain additional access to certain collections or items. If you have questions about access or logging in, please use the form on the Contact Page.
Ackert, A. K. (2017). Search for Heavy Stable Charged Particles √ at S = 13 TeV Utilizing a Multivariate Approach. Retrieved from http://purl.flvc.org/fsu/fd/FSU_2017SP_Ackert_fsu_0071E_13836
Heavy stable charged particles (HSCPs) have been searched for at the Large Hadron Collider since its initial data taking in 2010. The search for heavy stable charged particles provide a means of directly probing the new physics realm, as they produce a detector signature unlike any particle discovered to date. The goal of this research is to investigate an idea that was introduced in the later stages of 2010-2012 data taking period. Rather than utilizing the current tight selection on the calculated particle mass the hypothesis is that by incorporating a multivariate approach, specifically an artificial neural network, the remaining selection criteria could be loosened allowing for a greater signal acceptance while maintaining acceptable background rejection via the multivariate discriminator from the artificial neural network. The increase in signal acceptance and retention or increase in background rejection increases the discovery potential for HSCPs and as a secondary objective calculates improved limits on the HSCP signal models. The multivariate approach was developed and tested using 2.5 fb⁻¹ of 2015 data at √s = 13 TeV based on both the past tracker-only and Tracker+TOF HSCP analyses. The multivariate analyses were able to produce improved upper cross section limits on both expected and observed cross sections compared to the past 2015 results. The lower mass limits produced by the multivariate analyses are also improved, but the improvement was found to be less than 5% higher compared to the past 2015 HSCP search results. A final comparison of the multivariate approach to past HSCP searches was conducted on 12.9 fbfb⁻¹ of 2016 data at √s = 13 TeV. No statistically significant excess of data over background prediction is observed. Therefore no evidence of HSCPs is claimed. The tracker-only (Tracker+TOF) multivariate analysis produced lower mass limits of 1870 (1820) GeV for gluinos with 10% R-hadrons produced neutral, 1260 (1210) GeV for stops, 680 (670) GeV for decay-product staus, 340 (370) GeV for directly pair-produced staus, 720 (750) GeV for modified Drell-Yan |Q| = 1e, and 700 (900) GeV for modified Drell-Yan |Q| = 2e. Overall, the multivariate approach produced improved lower mass limits compared to the results from the past 2016 HSCP search. The overall improvements in cross section and mass limits using the multivariate approach produced the best limits on HSCPs to date. Furthermore the multivariate approach is shown as a viable method of searching for HSCPs. With the HSCP search covering a broad range of beyond the Standard Model physics, the lack of evidence and subsequent limits produced place important restrictions on the theoretical models that predict HSCPs.
A Dissertation submitted to the Department of Physics in partial fulfillment of the requirements for the degree of Doctor of Philosophy.
Bibliography Note
Includes bibliographical references.
Advisory Committee
Todd Adams, Professor Directing Dissertation; Jerry Magnan, University Representative; Harrison Prosper, Committee Member; Joseph Owens, Committee Member; Jorge Piekarewicz, Committee Member.
Publisher
Florida State University
Identifier
FSU_2017SP_Ackert_fsu_0071E_13836
Use and Reproduction
This Item is protected by copyright and/or related rights. You are free to use this Item in any way that is permitted by the copyright and related rights legislation that applies to your use. For other uses you need to obtain permission from the rights-holder(s). The copyright in theses and dissertations completed at Florida State University is held by the students who author them.
Ackert, A. K. (2017). Search for Heavy Stable Charged Particles √ at S = 13 TeV Utilizing a Multivariate Approach. Retrieved from http://purl.flvc.org/fsu/fd/FSU_2017SP_Ackert_fsu_0071E_13836