Presentation is loading. Please wait.

Presentation is loading. Please wait.

Photoemission Spectroscopy Dr. Xiaoyu Cui May.11.2013 Surface Canada 2013--workshop.

Published byDrusilla Bailey Modified over 8 years ago

Similar presentations

Presentation on theme: "Photoemission Spectroscopy Dr. Xiaoyu Cui May.11.2013 Surface Canada 2013--workshop."— Presentation transcript:

1 Photoemission Spectroscopy Dr. Xiaoyu Cui May.11.2013 Surface Canada 2013--workshop

2 Outline  Introduction  What you need to know…  Scientific view  Other…

3 Introduction h The photoelectric effect First experimental work performed by H.Hertz (1886), W.Halwachs(1998),von Lenard(1900) Theoretical explanation by Einstein(1905) Many properties of solids are determined by electrons near E F ; (conductivity, magnetism, superconductivity) Only a narrow energy range around E F is relevant for those properties Fermi surface

4 Advantage or disadvantage PES is really surface sensitive Within VUV region Cross sections are very small at high photon energy region!!

5 Physicist: Know: sample quality; physical properties (resistance; magnetic..) Want to know: Why? How to build the connection? Prefer to use: Angular resolved photoemission spectroscopy (ARPES) Chemist: Know: possible elements or compounds inside the system. Want to know: Chemical shifts? Bonding? Procedure? Reaction? Prefer to use: Traditional photoemission spectroscopy (XPS); Ambient pressure photoemission spectroscopy (APPES) What’s the interest in PES community?

6 Courtesy of Luc Patthey (SLS)

7

8

9 Emission Angle Kinetique Energie

10 Emission Angle Kinetique Energie

11 Emission Angle Kinetique Energie

12 Emission Angle Kinetique Energie

13 Emission Angle Kinetique Energie

14 Emission Angle Kinetique Energie

15 Emission Angle Kinetique Energie

16 Emission Angle Kinetique Energie

17 Emission Angle Kinetique Energie

18 Emission Angle Kinetique Energie

19 Emission Angle Kinetique Energie k // f  k i  2mE h 2 sin  

20 k // f  k i  2mE h 2 sin  

21 8K k // f  k i  2mE h 2 sin   

22 8K k // f  k i  2mE h 2 sin   

23 k // f  k i  2mE h 2 sin   

24 8K k // f  k i  2mE h 2 sin   

25 WHAT HAPPENED IN YOUR XPS LAB.. Energy Conservation You know h from Lab XPS using Al; Mg sources. Excitation energy are fixed at 1486.6 and 1253.6 eV You should ask for  (work function) from lab scientist. (ask them to make a Au Fermi at the same time if possible) *Work function will change with different system by few hundred meV You know how to transfer to binding energy from kinetic energy YOU ARE A EXPERT NOW!!!!!!!!

26 Quasi-particle Many-body interactions lead to a renormalization of the non-interacting electron dispersion (changes the effective mass of electrons) and a finite lifetime

27 el-mag interactionel-ph interaction Interaction Effects in Band Dispersion Computer simulation of Quasi-particle dispersion Including many-body interactions High-resolusion ARPES with tunable synchrotron radiation to determine the mass enhancement m*/m b interactions Bare band

28 Lifetime broadening mode electron-electron interaction electron-phonon coupling electron-magnon coupling electron-impurity scattering Debye temp. ~0.04 eV Band width 3~5 eV Mag. DOS ~0.4 eV for Ni, Fe Final state effect energy indep.

29 Quasiparticle evidence ~0.3 eV ~0.04 eV h =40 eV 15 K  E=9 meV Debye temp.  D = 470 K (k B  D = 40 meV) X.Y. Cui, PRB‏

30 Fermi Surface of Ni(110) Fermi Surfaces In condensed matter physics, the Fermi surface is an abstract boundary useful for predicting the thermal, electrical, magnetic, and optical properties of systems. The shape of the Fermi surface is derived from the periodicity and symmetry of the crystalline lattice and from the occupation of electronic energy bands. The existence of a Fermi surface is a direct consequence of the Pauli exclusion principle, which allows a maximum of one electron per quantum state.

31 h =100eV Linear_Vertical light h =100eV Linear_Horizontal light Matrix elements effect! Fermi Surfaces 11 11 22

32 Charging effect metalInsulator Kinetic Energy (eV)

33 How to fix it? Flood gun??Mental mesh?? Possible factor: Charge density; Sample homogeneity. S 2p Lead 4fd states

34 D.R.T. Zahn, G.N. Gavrila, M. Gorgoi Chem. Phys., 325 (1) (2006) 99 Inverse photoemission 15 nm thick film of DiMe-PTCDI

35 Auger procedure Fixed kinetic energy A N Titov’s group

36 Spin-polarized photoemission Bi film on Ag(111) COFFEE DATA FROM SLS Surface states with different spin

37 Time-resolved photoemission Uwe Bovensiepen’s data Dynamic evidence

38 Ambient pressure photoemission In situ!!

39

Download ppt "Photoemission Spectroscopy Dr. Xiaoyu Cui May.11.2013 Surface Canada 2013--workshop."

Similar presentations

Basic Nuclear Properties

Basic Nuclear Properties
Spectroscopy Photoelectron spectroscopy X-ray absorption spectroscopy

Spectroscopy Photoelectron spectroscopy X-ray absorption spectroscopy
Spectroscopy of Hybrid Inorganic/Organic Interfaces Electron Spectroscopy Dietrich RT Zahn.

Spectroscopy of Hybrid Inorganic/Organic Interfaces Electron Spectroscopy Dietrich RT Zahn.
Spectroscopy Photoelectron spectroscopy X-ray absorption spectroscopy

Spectroscopy Photoelectron spectroscopy X-ray absorption spectroscopy
Ion Beam Analysis techniques:

Ion Beam Analysis techniques:
Dispersive property of a G-M tube HV - + In the proportional region a G-M tube has dispersive properties 0 250 500 750 1 10 2 10 4 10 6 10 810 tube voltage.

Dispersive property of a G-M tube HV - + In the proportional region a G-M tube has dispersive properties tube voltage.
Budapest University of Technology and Economics Department of Electron Devices Microelectronics, BSc course Basic semiconductor physics.

Budapest University of Technology and Economics Department of Electron Devices Microelectronics, BSc course Basic semiconductor physics.
Quantum Mechanics and Spin-Valves Thomas Prevenslik QED Radiations Discovery Bay, Hong Kong The 13th IEEE Inter. Conf. on Nanotechnology, August 5-8, Beijing,

Quantum Mechanics and Spin-Valves Thomas Prevenslik QED Radiations Discovery Bay, Hong Kong The 13th IEEE Inter. Conf. on Nanotechnology, August 5-8, Beijing,
Probing Superconductors using Point Contact Andreev Reflection Pratap Raychaudhuri Tata Institute of Fundamental Research Mumbai Collaborators: Gap anisotropy.

Probing Superconductors using Point Contact Andreev Reflection Pratap Raychaudhuri Tata Institute of Fundamental Research Mumbai Collaborators: Gap anisotropy.
KAPITZA-DIRAC EFFECT Eric Weaver Phys 4P62. General Outline  Theorized in 1933 by Kapitza and Dirac  Reflection of electrons from standing light waves.

KAPITZA-DIRAC EFFECT Eric Weaver Phys 4P62. General Outline  Theorized in 1933 by Kapitza and Dirac  Reflection of electrons from standing light waves.
Ultraviolet Photoelectron Spectroscopy (UPS)

Ultraviolet Photoelectron Spectroscopy (UPS)
What experiments should we be doing? Dion L. Heinz University of Chicago.

What experiments should we be doing? Dion L. Heinz University of Chicago.
First of all, do you know any methods to check chemical composition? Or how you know what is what? First of all, do you know any methods to check chemical.

First of all, do you know any methods to check chemical composition? Or how you know what is what? First of all, do you know any methods to check chemical.
We use synchrotron-radiation based spectroscopies to measure the electronic structure of wide band gap semiconductors. Our goal is to understand how this.

We use synchrotron-radiation based spectroscopies to measure the electronic structure of wide band gap semiconductors. Our goal is to understand how this.
Light. Photons The photon is the gauge boson of the electromagnetic force. –Massless –Stable –Interacts with charged particles. Photon velocity depends.

Light. Photons The photon is the gauge boson of the electromagnetic force. –Massless –Stable –Interacts with charged particles. Photon velocity depends.
Catalysis and Catalysts - XPS X-Ray Electron Spectroscopy (XPS)  Applications: –catalyst composition –chemical nature of active phase –dispersion of active.

Catalysis and Catalysts - XPS X-Ray Electron Spectroscopy (XPS)  Applications: –catalyst composition –chemical nature of active phase –dispersion of active.
Physics 440 Condensed Matter Physics a.k.a. Materials Physics Solid-State Physics.

Physics 440 Condensed Matter Physics a.k.a. Materials Physics Solid-State Physics.
Alternative representation of QW Phase accumulation model.

Alternative representation of QW Phase accumulation model.
ARPES (Angle Resolved PhotoEmission Spectroscopy) Michael Browne 11/19/2007.

ARPES (Angle Resolved PhotoEmission Spectroscopy) Michael Browne 11/19/2007.
The electronic structures of 2D atomically uniform thin film S.- J. Tang, T. Miller, and T.-C. Chiang Department of Physics, University of Illinois at.

The electronic structures of 2D atomically uniform thin film S.- J. Tang, T. Miller, and T.-C. Chiang Department of Physics, University of Illinois at.

Similar presentations

Ads by Google