SPECTRAL ANALYSIS OF VOLUME OPERATOR IN LOOP QUANTUM GRAVITY FOR KINEMATICAL CASE

SPECTRAL ANALYSIS OF VOLUME OPERATOR IN LOOP QUANTUM GRAVITY FOR KINEMATICAL CASE

Loop Quantum Gravity has become one of the alternative solutions to quantum gravity. In this approach, the quantum effects are included into the General Relativity formulation through the Einstein-Hilbert Action using tetrads, resulting in quantized formulation for General Relativity. This formulati...

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Main Author: SEBASTIAN (NIM : 10214042), IGNATIUS
Format: Final Project
Language:Indonesia
Subjects:
Fisika
Online Access:https://digilib.itb.ac.id/gdl/view/27928
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Institution: Institut Teknologi Bandung
Language: Indonesia
id id-itb.:27928
spelling id-itb.:279282018-08-31T10:55:49ZSPECTRAL ANALYSIS OF VOLUME OPERATOR IN LOOP QUANTUM GRAVITY FOR KINEMATICAL CASE SEBASTIAN (NIM : 10214042), IGNATIUS Fisika Indonesia Final Project Gauss Constraint, Loop Quantum Gravity, Spin Network, Volume Operator. INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/27928 Loop Quantum Gravity has become one of the alternative solutions to quantum gravity. In this approach, the quantum effects are included into the General Relativity formulation through the Einstein-Hilbert Action using tetrads, resulting in quantized formulation for General Relativity. This formulation introduced a pair of new variables called Ashtekar's variable, which brought the group representation of SU(2). These variables are successfully used to model that in the quantum size, the space is actually discretized in the order of Planck length. The results came from the geometric operators, area and volume, which is formed by Ashtekar's variables. These operators have discrete eigenvalues, which is caused by the dependence of eigenvalues on the spin j of the spin network. The regularization process of these operators came from the classical definition of area and volume. Thus, the eigenvalues of area operator and volume operator are respectively the area and volume of the measured space. However, generally, there are two types of volume operator, the Ashtekar-Lewandowski operator and the Rovelli-Smolin operator. The significant difference between these two operators is the fact that Ashtekar-Lewandowski operator is sensitive to the direction of the spin network's link, while Rovelli-Smolin operator is not. This difference will result in a different spectrum of eigenvalue between these operators if they are applied to the same spin network. 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
topic Fisika
spellingShingle Fisika
SEBASTIAN (NIM : 10214042), IGNATIUS
SPECTRAL ANALYSIS OF VOLUME OPERATOR IN LOOP QUANTUM GRAVITY FOR KINEMATICAL CASE
description Loop Quantum Gravity has become one of the alternative solutions to quantum gravity. In this approach, the quantum effects are included into the General Relativity formulation through the Einstein-Hilbert Action using tetrads, resulting in quantized formulation for General Relativity. This formulation introduced a pair of new variables called Ashtekar's variable, which brought the group representation of SU(2). These variables are successfully used to model that in the quantum size, the space is actually discretized in the order of Planck length. The results came from the geometric operators, area and volume, which is formed by Ashtekar's variables. These operators have discrete eigenvalues, which is caused by the dependence of eigenvalues on the spin j of the spin network. The regularization process of these operators came from the classical definition of area and volume. Thus, the eigenvalues of area operator and volume operator are respectively the area and volume of the measured space. However, generally, there are two types of volume operator, the Ashtekar-Lewandowski operator and the Rovelli-Smolin operator. The significant difference between these two operators is the fact that Ashtekar-Lewandowski operator is sensitive to the direction of the spin network's link, while Rovelli-Smolin operator is not. This difference will result in a different spectrum of eigenvalue between these operators if they are applied to the same spin network.
format Final Project
author SEBASTIAN (NIM : 10214042), IGNATIUS
author_facet SEBASTIAN (NIM : 10214042), IGNATIUS
author_sort SEBASTIAN (NIM : 10214042), IGNATIUS
title SPECTRAL ANALYSIS OF VOLUME OPERATOR IN LOOP QUANTUM GRAVITY FOR KINEMATICAL CASE
title_short SPECTRAL ANALYSIS OF VOLUME OPERATOR IN LOOP QUANTUM GRAVITY FOR KINEMATICAL CASE
title_full SPECTRAL ANALYSIS OF VOLUME OPERATOR IN LOOP QUANTUM GRAVITY FOR KINEMATICAL CASE
title_fullStr SPECTRAL ANALYSIS OF VOLUME OPERATOR IN LOOP QUANTUM GRAVITY FOR KINEMATICAL CASE
title_full_unstemmed SPECTRAL ANALYSIS OF VOLUME OPERATOR IN LOOP QUANTUM GRAVITY FOR KINEMATICAL CASE
title_sort spectral analysis of volume operator in loop quantum gravity for kinematical case
url https://digilib.itb.ac.id/gdl/view/27928
_version_ 1822922410942267392

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