© 2017

Fermi Surface and Quantum Critical Phenomena of High-Temperature Superconductors


Part of the Springer Theses book series (Springer Theses)

Table of contents

  1. Front Matter
    Pages i-xv
  2. Carsten Matthias Putzke
    Pages 1-13
  3. Carsten Matthias Putzke
    Pages 15-43
  4. Carsten Matthias Putzke
    Pages 45-79
  5. Carsten Matthias Putzke
    Pages 121-143
  6. Carsten Matthias Putzke
    Pages 145-159
  7. Back Matter
    Pages 161-162

About this book


This thesis provides a detailed introduction to quantum oscillation measurement and analysis and offers a connection between Fermi surface properties and superconductivity in high-temperature superconductors. It also discusses the field of iron-based superconductors and tests the models for the appearance of nodes in the superconducting gap of a 111-type pnictide using quantum oscillation measurements combined with band structure calculation.

The same measurements were carried out to determine the quasiparticle mass in BaFe2(As1-xPx)2, which is strongly enhanced at  the expected quantum critical point. While the lower superconducting critical field shows evidence of quantum criticality, the upper superconducting critical field is not influenced by the quantum critical point. These findings contradict conventional theories, demonstrating the need for a theoretical treatment of quantum critical superconductors, which has not been addressed to date.

The quest to discover similar evidence in the cuprates calls for the application of extreme conditions. As such, quantum oscillation measurements were performed under high pressure in a high magnetic field, revealing a negative correlation between quasiparticle mass and superconducting critical temperature.


Quantum Critical Superconductors Quantum Criticality Quantum Oscillation de Haas-van Alphen Shubnikov-de Haas High Temperature Superconductor Fermi Surface Measurements Cuprate Superconductors Iron-based Superconductors Abrikosov Vortex Core States Quasi-particle Mass Fermi Surface Evolution Under Hydrostatic Pressure High Magnetic Fields

Authors and affiliations

  1. 1.H.H. Wills Laboratory of PhysicsUniversity of BristolBristolUnited Kingdom

Bibliographic information