Functional Renormalization and Ultracold Quantum Gases [electronic resource] / by Stefan Fl�rchinger.

By: Fl�rchinger, Stefan [author.]Contributor(s): SpringerLink (Online service)Material type: TextTextSeries: Springer Theses, Recognizing Outstanding Ph.D. ResearchPublisher: Berlin, Heidelberg : Springer Berlin Heidelberg : Imprint: Springer, 2010Description: X, 202 p. 58 illus. online resourceContent type: text Media type: computer Carrier type: online resourceISBN: 9783642141133Subject(s): Physics | Quantum physics | Phase transformations (Statistical physics) | Condensed materials | Condensed matter | Low temperature physics | Low temperatures | Physics | Theoretical, Mathematical and Computational Physics | Quantum Physics | Low Temperature Physics | Quantum Gases and CondensatesAdditional physical formats: Printed edition:: No titleDDC classification: 530.1 LOC classification: QC19.2-20.85Online resources: Click here to access online
Contents:
The Wetterich Equation -- Generalized Flow Equation -- Truncations -- Cutoff Choices -- Investigated Models -- Symmetries -- Truncated Flow Equations -- Few-Body Physics -- Many-Body Physics -- Conclusions -- Appendices.
In: Springer eBooksSummary: Modern techniques from quantum field theory are applied in this work to the description of ultracold quantum gases. This leads to a unified description of many phenomena including superfluidity for bosons and fermions, classical and quantum phase transitions, different dimensions, thermodynamic properties and few-body phenomena as bound state formation or the Efimov effect. The non-perturbative treatment with renormalization group flow equations can account for all known limiting cases by solving one single equation. It improves previous results quantitatively and brings qualitatively new insights. As an example, new quantum phase transitions are found for fermions with three spin states. Ultracold atomic gases can be seen as an interesting model for features of high energy physics and for condensed matter theory. The research reported in this thesis helps to solve the difficult complexity problem in modern theoretical physics.
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The Wetterich Equation -- Generalized Flow Equation -- Truncations -- Cutoff Choices -- Investigated Models -- Symmetries -- Truncated Flow Equations -- Few-Body Physics -- Many-Body Physics -- Conclusions -- Appendices.

Modern techniques from quantum field theory are applied in this work to the description of ultracold quantum gases. This leads to a unified description of many phenomena including superfluidity for bosons and fermions, classical and quantum phase transitions, different dimensions, thermodynamic properties and few-body phenomena as bound state formation or the Efimov effect. The non-perturbative treatment with renormalization group flow equations can account for all known limiting cases by solving one single equation. It improves previous results quantitatively and brings qualitatively new insights. As an example, new quantum phase transitions are found for fermions with three spin states. Ultracold atomic gases can be seen as an interesting model for features of high energy physics and for condensed matter theory. The research reported in this thesis helps to solve the difficult complexity problem in modern theoretical physics.

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