Disorder at First-Order Classical and Quantum Phase Transitions
tarafından
 
Ibrahim, Ahmed Khalil, author.

Başlık
Disorder at First-Order Classical and Quantum Phase Transitions

Yazar
Ibrahim, Ahmed Khalil, author.

ISBN
9780438113244

Yazar Ek Girişi
Ibrahim, Ahmed Khalil, author.

Fiziksel Tanımlama
1 electronic resource (149 pages)

Genel Not
Source: Dissertation Abstracts International, Volume: 79-11(E), Section: B.
 
Advisors: Thomas Vojta Committee members: Aleksandr Chernatynskiy; José A. Hoyos; Paul E. Parris; Gerald Wilemski.

Özet
This dissertation studies the effects of quenched disorder on classical, quantum and nonequilibrium phase transitions. After a short introduction which covers the basic concepts of phase transitions, finite-size scaling and random disorder, the dissertation focuses on four separate but related projects. First, we investigate the influence of quenched disorder with long-range spatial correlations on the nonequilibrium phase transitions in the contact process. We show that the long-range correlations increase the probability to find rare atypical regions in the sample. This leads to enhanced Griffiths singularities and changes the universality class of the transition.
 
Project 2 and 3 focus on disorder at first-order phase transitions. In project 2, we analyze the phase transitions of a classical Ashkin-Teller magnet. We demonstrate that the first-order classical phase transition is destroyed by disorder, and the resulting continuous transition belongs to the clean two-dimensional Ising universality class with logarithmic corrections.
 
Project 3 investigates the fate of the first-order quantum phase transition in the quantum Ashkin-Teller model by large-scale Monte Carlo simulations. We find that disorder rounds the first-order quantum phase transition just as in the classical case. The resulting critical behavior depends on the strength of the inter-color coupling in the quantum Ashkin- Teller model. This leads to two different regimes, the weak and strong coupling regimes, both of which feature infinite-randomness critical behavior but in different universality classes.
 
Finally, we study the quantum phase transition of a disordered nanowire from superconductor to metallic behavior. We show that the critical behavior is of infinite-random type and belongs to the random transverse-field Ising universality class as predicted by strong disorder renormalization group results.

Notlar
School code: 0587

Konu Başlığı
Physics.

Tüzel Kişi Ek Girişi
Missouri University of Science and Technology. Physics.

Elektronik Erişim
http://gateway.proquest.com/openurl?url_ver=Z39.88-2004&rft_val_fmt=info:ofi/fmt:kev:mtx:dissertation&res_dat=xri:pqm&rft_dat=xri:pqdiss:10787906


Yer NumarasıDemirbaş NumarasıShelf LocationShelf LocationHolding Information
XX(689918.1)689918-1001Proquest E-Tez KoleksiyonuProquest E-Tez Koleksiyonu