Glasses at ultra-low temperatures present several puzzling phenomena. A notable example is the anomalous (i.e., non-Debye) behavior of thermodynamic quantities at temperatures lower than 1 K. A comprehensive quantum theory able to explain these phenomena has not been developed so far. In this thesis, we tackle this long-standing problem with different and innovative perspectives, employing various physical models, and several analytical and numerical techniques. We mainly explore two different but complementary approaches. In the first approach, we investigate the thermodynamics of models for ultra-low temperature glasses, with particular attention to mean-field models. Specifically, exploiting hard-sphere systems and constraint satisfaction problems as a minimal model for structural glasses, we explore their jamming transition both in the classical and the quantum regime. In the second approach, we focus on finite-dimensional models. We analyze the quantum dynamics of the two-level system model for glasses and generic many-body localized systems, providing clues for the presence of a deep connection between glasses and quantum many-body localized systems. This thesis aims at estimating both qualitatively and quantitatively the effects of quantum mechanics on glasses at ultra-low temperatures. In the literature, only a few studies have considered glasses deep in their quantum regime, partly due to the analytical and computational challenges this posits. Nevertheless, this perspective promises to have wide-ranging applications. One of our ambitious goals is to take a first, substantial step to unveil the possible origin of long-standing discrepancies observed between theory and experiments in ultra-low temperature glasses. Moreover, we would like to predict the presence of new experimental regimes that might be interesting to investigate.

Quantum effects in glasses at ultra-low temperatures / Artiaco, Claudia. - (2021 Sep 29).

Quantum effects in glasses at ultra-low temperatures

Artiaco, Claudia
2021-09-29

Abstract

Glasses at ultra-low temperatures present several puzzling phenomena. A notable example is the anomalous (i.e., non-Debye) behavior of thermodynamic quantities at temperatures lower than 1 K. A comprehensive quantum theory able to explain these phenomena has not been developed so far. In this thesis, we tackle this long-standing problem with different and innovative perspectives, employing various physical models, and several analytical and numerical techniques. We mainly explore two different but complementary approaches. In the first approach, we investigate the thermodynamics of models for ultra-low temperature glasses, with particular attention to mean-field models. Specifically, exploiting hard-sphere systems and constraint satisfaction problems as a minimal model for structural glasses, we explore their jamming transition both in the classical and the quantum regime. In the second approach, we focus on finite-dimensional models. We analyze the quantum dynamics of the two-level system model for glasses and generic many-body localized systems, providing clues for the presence of a deep connection between glasses and quantum many-body localized systems. This thesis aims at estimating both qualitatively and quantitatively the effects of quantum mechanics on glasses at ultra-low temperatures. In the literature, only a few studies have considered glasses deep in their quantum regime, partly due to the analytical and computational challenges this posits. Nevertheless, this perspective promises to have wide-ranging applications. One of our ambitious goals is to take a first, substantial step to unveil the possible origin of long-standing discrepancies observed between theory and experiments in ultra-low temperature glasses. Moreover, we would like to predict the presence of new experimental regimes that might be interesting to investigate.
29-set-2021
Fabrizio, Michele
Scardicchio, Antonello
Artiaco, Claudia
File in questo prodotto:
File Dimensione Formato  
thesis_artiaco.pdf

accesso aperto

Tipologia: Tesi
Licenza: Non specificato
Dimensione 12.72 MB
Formato Adobe PDF
12.72 MB Adobe PDF Visualizza/Apri

I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.

Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.11767/124649
Citazioni
  • ???jsp.display-item.citation.pmc??? ND
  • Scopus ND
  • ???jsp.display-item.citation.isi??? ND
social impact