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How might a Fermi surface die?

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Presentation on theme: "How might a Fermi surface die?"— Presentation transcript:

1 How might a Fermi surface die?
T. Senthil

2 Electrons in metals

3 Modern solid state physics

4 A common phase diagram Non Fermi Liquid T Phase A Phase B Tuning
parameter

5 Example 1: High temperature superconducting materials
Pseudo gap AF Mott insulator Non-fermi liquid metal Fermi liquid

6 Example 2: Magnetic ordering in certain rare earth alloys CePd2Si2, CeCu6-xAux, YbRh2Si2,……
Metal Non –fermi liquid

7 Representative data on YbRh2Si2
Custers et al, Nature, 2003 Trovarelli et al, PRL 2000 B(T) T-dependence of resistivity at critical point: ρ(T) ~ T for three decades in temperature! Fermi liquid Magnetic metal Non fermi liquid

8 Origin of non-fermi liquid physics?
T Tuning parameter Phase A Phase B Non Fermi Liquid

9 So possibly……….

10 Recent clue from experiments

11 Killing a Fermi surface

12 Geometry of Fermi surface of CeRhIn5
Example: Evolution of Fermi surface across the magnetic phase transition in CeRhIn5 H. Shishido, R. Settai, H. Harima, & Y. Onuki, JPSJ 74, 1103 (2005)

13 A simple theoretical example

14 Evolution from metal to insulator

15 Possible experimental realization of a second order Mott transition

16 Another example: High temperature superconducting materials
Pseudo gap AF Mott insulator Non-fermi liquid metal Fermi liquid

17

18 Basic question for theory
How can an entire Fermi surface disappear continuously?

19 Even more basic: What is the Fermi surface?

20 How might the Fermi surface die?

21 Electronic structure at criticality: ``Critical Fermi surface”

22 Why a critical Fermi surface?

23 Evolution of single particle gap

24 Why a critical Fermi surface? Evolution of momentum distribution

25 Killing a Fermi surface

26 Some obvious consequences/questions

27 Scaling phenomenology at a quantum critical point with a
critical Fermi surface?

28 Critical Fermi surface: scaling for single particle physics

29 New possibility: angle dependent exponents

30 Leaving the critical point

31

32 Implications of angle dependent exponents

33 Finite T crossovers

34 Summary A Fermi surface may die through a second order phase transition -at the critical point the Landau quasiparticle is destroyed but the Fermi surface is preserved ( the `critical Fermi surface’) => non-fermi liquid Presence of critical fermi surface will change the scaling phenomenology associated with universal critical singularities. Concrete model calculations with a critical Fermi surface exist Future – many challenges Tests of scaling in experiments Calculational framework?

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