Book contents
- Frontmatter
- Contents
- Preface
- 1 Introduction
- 2 Non-interacting electron gas
- 3 Born–Oppenheimer approximation
- 4 Second quantization
- 5 Hartree–Fock approximation
- 6 Interacting electron gas
- 7 Local magnetic moments in metals
- 8 Quenching of local moments: the Kondo problem
- 9 Screening and plasmons
- 10 Bosonization
- 11 Electron–lattice interactions
- 12 Superconductivity in metals
- 13 Disorder: localization and exceptions
- 14 Quantum phase transitions
- 15 Quantum Hall and other topological states
- 16 Electrons at strong coupling: Mottness
- Index
- References
14 - Quantum phase transitions
Published online by Cambridge University Press: 05 June 2012
- Frontmatter
- Contents
- Preface
- 1 Introduction
- 2 Non-interacting electron gas
- 3 Born–Oppenheimer approximation
- 4 Second quantization
- 5 Hartree–Fock approximation
- 6 Interacting electron gas
- 7 Local magnetic moments in metals
- 8 Quenching of local moments: the Kondo problem
- 9 Screening and plasmons
- 10 Bosonization
- 11 Electron–lattice interactions
- 12 Superconductivity in metals
- 13 Disorder: localization and exceptions
- 14 Quantum phase transitions
- 15 Quantum Hall and other topological states
- 16 Electrons at strong coupling: Mottness
- Index
- References
Summary
In the previous chapter, we discussed both the insulator–superconductor and the insulator–metal transitions. As such transitions are disorder or magnetic-field tuned, thermal fluctuations play no role. Phase transitions of the insulator–superconductor or insulator–metal type are called quantum phase transitions. Such phase transitions are not controlled by changing the temperature, as in the melting of ice or the λ-point of liquid helium, but rather by changing some system parameter, such as the number of defects or the concentration of charge carriers. In all such instances, the tuning parameter transforms the system between quantum mechanical states that either look different topologically (as in the transition between localized and extended electronic states) or have distinctly different magnetic properties. As quantum mechanics underlies such phase transitions, all quantum phase transitions obtain at the absolute zero of temperature and thus are governed by a T = 0 quantum critical point. While initially surprising, this state of affairs is expected, because quantum mechanics is explicitly a zero-temperature theory of matter. Of course, this is of no surprise to chemists who have known for quite some time that numerous materials can exhibit vastly distinct properties simply by changing the chemical composition and, most importantly, that such transformations persist down to zero temperature. Common examples include turning insulators such as the layered cuprates into superconductors simply by chemical doping or semiconductors into metals once again by doping, or ferromagnets such as Li(Ho, Tb)x Y1-x F4 into a spin glass (AR1998) by altering x.
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- Chapter
- Information
- Advanced Solid State Physics , pp. 289 - 316Publisher: Cambridge University PressPrint publication year: 2012