Phase transitions in novel superfluids and systems with correlated disorder

Meier, Hannes

January 2015

Condensed matter systems undergoing phase transitions rarely allow exact solutions. The presence of disorder renders the situation  even worse but collective Monte Carlo methods and parallel algorithms allow numerical descriptions. This thesis considers classical phase transitions in disordered spin systems in general and in effective models of superfluids with disorder and novel interactions in particular. Quantum phase transitions are considered via a quantum to classical mapping. Central questions are if the presence of defects changes universal properties and what qualitative implications follow for experiments. Common to the cases considered is that the disorder maps out correlated structures. All results are obtained using large-scale Monte Carlo simulations of effective models capturing the relevant degrees of freedom at the transition. Considering a model system for superflow aided by a defect network, we find that the onset properties are significantly altered compared to the $\lambda$-transition in $^{4}$He. This has qualitative implications on expected experimental signatures in a defect supersolid scenario. For the Bose glass to superfluid quantum phase transition in 2D we determine the quantum correlation time by an anisotropic finite size scaling approach. Without a priori assumptions on critical parameters, we find the critical exponent $z=1.8 \pm 0.05$ contradicting the long standing result $z=d$. Using a 3D effective model for multi-band type-1.5 superconductors we find that these systems possibly feature a strong first order vortex-driven phase transition. Despite its short-range nature details of the interaction are shown to play an important role. Phase transitions in disordered spin models exposed to correlated defect structures obtained via rapid quenches of critical loop and spin models are investigated. On long length scales the correlations are shown to decay algebraically. The decay exponents are expressed through known critical exponents of the disorder generating models. For cases where the disorder correlations imply the existence of a new long-range-disorder fixed point we determine the critical exponents of the disordered systems via finite size scaling methods of Monte Carlo data and find good agreement with theoretical expectations. / <p>QC 20150306</p>

condensed matter physics

phase transitions

critical phenomena

spin models

quantum phase transitions

quantum fluids

superfluidity

superconductivity

disordered systems

Bose glass

dirty bosons

vortex pinning

statistical mechanics

Monte Carlo simulation

Wolff algorithm

classical worm algorithm

Wang-Landau algorithm

Effects of power-law correlated disorder on a 3D XY model / Effekterna av potenslagskorrelerad oordning på 3D XY-modeller

Broms, Philip

January 2022

This thesis investigates the effects of power-law correlated disorder on a three-dimensional XY model and the Weinrib-Halperin disorder relevance criterion’s pre-dictive ability. Ising models are used as a map to realise disorder couplings. Simula-tions are conducted using hybrid Monte Carlo method constituting Metropolis’ andWolff’s algorithms. Two cases using two-dimensional and three-dimensional Isinggenerated disorder corresponding to (d + 1)- and d-dimensional models are tested.In addition, a superficial scaling analysis is performed to highlight the change ofuniversality class.It is shown that magnetisation, response functions and Binder ratio along withits temperature derivative display stark differences from the pure XY model case.The results agree with the Weinrib-Halperin criterion in terms of predicting achange of universality class but show a discrepancy in both qualitative and nu-merical results. The main new result is that power-law correlated disorder canintroduce two phase transitions at different critical couplings. This is in disagree-ment with prior established theory and predicts new physics to be investigated insuperconductors and superfluids with correlated disorder. / Det här examensarbetet undersöker hur potenslagskorrelerad oordning påverkar en tredimensionell XY-modell samt förutsägelseförmågan hos Weinrib-Halperins oordningskriterium. Oordningen realiseras genom varierande kopplingsstyrka som definieras med hjälp av Isingmodeller. Simuleringar utförs med hjälp av en Monte Carlo-hybridmetod bestående av Metropolis och Wolffs algoritmer. Undersökningen innefattar oordning genererad av tvådimensionella samt tredimensionella Isingmodeller med syftet att emulera oordning hos (d + 1)- och d-dimensionella modeller. Dessutom utförs en ytlig skalningsanalys för att tydliggöra förändringen hos universalitetsklassen. Resultaten uppvisar markanta skillnader från en ren XY-modell i magnetiseringen, responsfunktionerna och Binderparametern med temperaturderivata. Resultaten bekräftar Weinrib-Halperin-oordningskriteriets förmåga att förutsäga förändring hos universalitetsklassen men avviker från exakta kvalitativa och kvantitativa prognoser. Det huvudsakliga nya resultatet är att potenslagskorrelerad oordning kan introducera två fasövergångar vid två olika kritiska kopplingar. Detta motsäger den etablerade teorin och pekar på ny fysik att utreda hos supraledare och suprafluider med korrelerad oordning.

Condensed matter physics

Ising model

XY model

Markov Chain Monte Carlo

Phase transition

Disorder

Theoretical physics

Wolff algorithm

Kondenserade materians teori

Isingmodell

XY-modell

Markovkedje-Monte Carlo-metoder

Teoretisk fysik

Oordning

Fasövergångar

Wolffalgoritmen

Physical Sciences

Fysik