DETERMINATION OF BOUNDS OF DARKSTRAHLUNG MODEL FROM THE LHC AND FERMI-LAT DATA

The existence of dark matter in the universe has been proven by various observations at the galaxy scale, the galaxy cluster, and the cosmology scale. Based on the data from Wilkinson Microwave Anisotropy Probe (WMAP), dark matter fills 24% of our universe. Until now, dark matter only interacts g...

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Main Author:	Hidayat, Michael
Format:	Theses
Language:	Indonesia
Online Access:	https://digilib.itb.ac.id/gdl/view/49025
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Institution:	Institut Teknologi Bandung
Language:	Indonesia

id	id-itb.:49025
spelling	id-itb.:490252020-08-26T21:47:25ZDETERMINATION OF BOUNDS OF DARKSTRAHLUNG MODEL FROM THE LHC AND FERMI-LAT DATA Hidayat, Michael Indonesia Theses Fermi-LAT, LHC, dark matter, darkstrahlung model, effective operator, WIMP. INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/49025 The existence of dark matter in the universe has been proven by various observations at the galaxy scale, the galaxy cluster, and the cosmology scale. Based on the data from Wilkinson Microwave Anisotropy Probe (WMAP), dark matter fills 24% of our universe. Until now, dark matter only interacts gravitationally with the other matters and is hypothezied to interact very weak with the other matters based on Weakly Interacting Massive Particles (WIMP) scenario. The other dark matter’s characteristics, such as its mass, spin, and the other interactions are still elusive. Therefore, in other to get the other dark matter’s characteristic, many assumptions and models are proposed, one of them is the darkstrahlung model. Darkstrahlung model is a model that observes the presence of dark gauge boson from U(1)D group which mixes with U(1)Y standard model particles through a kinetic mixing operator. The interaction between particle with q can be written in the form of effective operator, that is 1 2 V (q q)( ) dan 1 2 A (q 5q)( 5). This model also assumes that the dark matter is charged under the U(1)D, hence dark matter particle then will radiate Z0 boson, and the Z0 boson then will decay to leptonantilepton. The darkstrahlung model then will be observed at LHC with MadGraph simulation and at Fermi-LAT with MadDM simulation. The simulation is carried out using Z’ boson from 130 – 300 GeV and it is assumed as well mZ0 < 2m. The results from both observations are then compared and obtained a constraint for darkstrahlung model. The result we get that darkstrahlung model bounds for both effective operator 1 2 V (q q)( ) dan 1 2 A (q 5q)( 5) are better bound at LHC than Fermi-LAT. text
institution	Institut Teknologi Bandung
building	Institut Teknologi Bandung Library
continent	Asia
country	Indonesia Indonesia
content_provider	Institut Teknologi Bandung
collection	Digital ITB
language	Indonesia
description	The existence of dark matter in the universe has been proven by various observations at the galaxy scale, the galaxy cluster, and the cosmology scale. Based on the data from Wilkinson Microwave Anisotropy Probe (WMAP), dark matter fills 24% of our universe. Until now, dark matter only interacts gravitationally with the other matters and is hypothezied to interact very weak with the other matters based on Weakly Interacting Massive Particles (WIMP) scenario. The other dark matter’s characteristics, such as its mass, spin, and the other interactions are still elusive. Therefore, in other to get the other dark matter’s characteristic, many assumptions and models are proposed, one of them is the darkstrahlung model. Darkstrahlung model is a model that observes the presence of dark gauge boson from U(1)D group which mixes with U(1)Y standard model particles through a kinetic mixing operator. The interaction between particle with q can be written in the form of effective operator, that is 1 2 V (q q)( ) dan 1 2 A (q 5q)( 5). This model also assumes that the dark matter is charged under the U(1)D, hence dark matter particle then will radiate Z0 boson, and the Z0 boson then will decay to leptonantilepton. The darkstrahlung model then will be observed at LHC with MadGraph simulation and at Fermi-LAT with MadDM simulation. The simulation is carried out using Z’ boson from 130 – 300 GeV and it is assumed as well mZ0 < 2m. The results from both observations are then compared and obtained a constraint for darkstrahlung model. The result we get that darkstrahlung model bounds for both effective operator 1 2 V (q q)( ) dan 1 2 A (q 5q)( 5) are better bound at LHC than Fermi-LAT.
format	Theses
author	Hidayat, Michael
spellingShingle	Hidayat, Michael DETERMINATION OF BOUNDS OF DARKSTRAHLUNG MODEL FROM THE LHC AND FERMI-LAT DATA
author_facet	Hidayat, Michael
author_sort	Hidayat, Michael
title	DETERMINATION OF BOUNDS OF DARKSTRAHLUNG MODEL FROM THE LHC AND FERMI-LAT DATA
title_short	DETERMINATION OF BOUNDS OF DARKSTRAHLUNG MODEL FROM THE LHC AND FERMI-LAT DATA
title_full	DETERMINATION OF BOUNDS OF DARKSTRAHLUNG MODEL FROM THE LHC AND FERMI-LAT DATA
title_fullStr	DETERMINATION OF BOUNDS OF DARKSTRAHLUNG MODEL FROM THE LHC AND FERMI-LAT DATA
title_full_unstemmed	DETERMINATION OF BOUNDS OF DARKSTRAHLUNG MODEL FROM THE LHC AND FERMI-LAT DATA
title_sort	determination of bounds of darkstrahlung model from the lhc and fermi-lat data
url	https://digilib.itb.ac.id/gdl/view/49025
_version_	1822000260640145408

DETERMINATION OF BOUNDS OF DARKSTRAHLUNG MODEL FROM THE LHC AND FERMI-LAT DATA

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