Angle-resolved photoemission spectroscopy

Condensed matter experiments

ARPES
Neutron scattering
X-ray spectroscopy
Quantum oscillations
Scanning tunneling microscopy

An Experimental Setup of Angle-Resolved Photoemission Spectroscopy

Photoemission and metals

Angle-resolved photoemission spectroscopy (ARPES), is a direct experimental technique to observe the distribution of the electrons (more precisely, the density of single-particle electronic excitations) in the reciprocal space of solids. The technique is a refinement of ordinary photoemission spectroscopy, studying photoemission of electrons from a sample achieved usually by illumination with soft X-rays. ARPES is one of the most direct methods of studying the electronic structure of the surface of solids.

ARPES gives information on the direction, speed and scattering process of valence electrons in the sample being studied (usually a solid). This means that information can be gained on both the energy and momentum of an electron, resulting in detailed information on band dispersion and Fermi surface.

The technique is also known as ARUPS (angle-resolved ultraviolet photoemission spectroscopy) when using ultraviolet light (as opposed to X-rays) to generate photoemission.

Theory

From conservation of energy, we have

E = \hbar \omega - E_{f} - \phi

where

$\hbar \omega$ is the incoming photon energy — measured
$E$ is the binding energy of the electron
$E_{f}$ is the kinetic energy of the outgoing electron — measured
$\phi$ is the electron work function (energy required to remove electron from sample to vacuum)

Photon momentum is often neglected because of its relatively small contribution compared with electron momentum.

In the typical case, where the surface of the sample is smooth, translational symmetry requires that the component of electron momentum in the plane of the sample be conserved:

\hbar k_{i\parallel}=\hbar k_{f\parallel}=\sqrt{2m E_f}\sin\theta

where

$\hbar k_f$ is the momentum of the outgoing electron — measured by angle
$\hbar k_i$ is the initial momentum of the electron

However, the normal component of electron momentum $k_{i\perp}$ might not be conserved. The typical way of dealing with this is to assume that the final in-crystal states are free-electron-like, in which case one has

k_{i\perp}=\frac{1}{\hbar}\sqrt{2m(E_f \cos^2\theta+V_0)}

in which $V_0$ denotes the band depth from vacuum, including electron work function $\phi$ ; $V_0$ can be determined by examining only the electrons emitted perpendicular to the surface, measuring their kinetic energy as a function of incident photon energy.

The equations for energy and momentum can be solved to determine the dispersion relation between the binding energy, $E$ , and the wave vector, $\mathbf{k}_i=\mathbf{k}_{i\parallel}+\mathbf{k}_{i\perp}$ , of the electron.

External links

Andrea Damascelli, "Probing the Electronic Structure of Complex Systems by ARPES", Physica Scripta T109, 61-74 (2004)
Angle-resolved photoemission spectroscopy of the cuprate superconductors (Review Article) (2002)
ARPES experiment in fermiology of quasi-2D metals (Review Article) (2014)

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Angle-resolved photoemission spectroscopy

Theory

See also

External links