Laser-based ARPES (Angle-Resolved Photo-Emission Spectroscopy) is a form of ARPES that uses a laser as an excitation source. Laser-based ARPES is operated with a narrow bandwidth UV laser source and offers several advantages over synchrotron radiation: A laser fits on a table (ok… a large table), and experiments can be performed at any time and independently of rare beam times in synchrotron facilities.

More technically speaking, a narrow-band UV laser offers a contantly high photon flux with an extremely high energy resolution of up to typ. ≤0.5 meV. For comparison, the energy resolution of synchrotron radiation is typically in the range of 5 – 20 meV – and is therefore worse than the resolution of a good energy analyzer with about 1 meV.

The photon energy of the laser source can be varied between 5.77 eV and 6.5 eV. As these are low-energy photons, the Angle-Resolved Photo-Emission Spectroscopy benefits because the bulk sensitivity is significantly enhanced and the momentum resolution increased (compared to synchrotron radiation).

Low-energy photons are sufficient to induce photoemission in many samples. However, it should be noted that due to the lower photon energy compared to synchrotron radiation, Laser-ARPES is particularly suitable for the measurement of electronic states close to the Fermi level.

Tunable deep-UV pulses from 190 … 215 nm / 6.5 … 5.77 eV are available with APE’s ARPES-laser source, constiting of a HarmoniXX FHG in combination with Levante Emerald HP.

The energy-tunable system provides high laser power in the range of several mW. Its brillant and monochromatic laser light is ideally suited for high-resolution ARPES (Angle-resolved Photoemission Spectroscopy) or ARUPS (Angle-resolved Ultraviolet Photoemission Spectroscopy).

• Tunable (Vacuum)-UV from 190 … 215 nm / 6.5 … 5.77 eV
• Extremely narrow spectral bandwidth of typ. ≤0.5 meV
• High photon flux of typ. >10^14 photons/s
• Exceptional beam quality of M² <1.2
• Automated wavelength tuning via software
• Ideally suited for table-top laser-based ARPES / ARUPS

ARPES maps of graphene/Ir(111) sample measured with laser around normal emission geometry showing the Rashbasplit of graphene/Ir(111) surface state. Two different entrance slits of the Electron Analyzer were used, resulting in different energy resolution (marked in the figure).

Graphene/Ir(111).RT
hv = 6.31 eV
Lens mode: WAM
Nr of energy points: 251 (Sweep mode)
Nr of 0-angle channels: 300

Dependence on Temperature. 3D ARPES data sets for graphene/Ir(111) sample measured with laser (lens mode: WAM). Measurements were performed at T=300 K (RT, see image) and T=120 K (LT, not shown here).

Graphene/Ir(111).LT
polar β-scan around NE
hv = 6.31 eV
Nr of energy points: 251
Nr of Θ-angle channels: 300
Nr of β-angle steps: 101
Total acquisition time: 50 min

The HarmoniXX allows access to the wavelength range of 190 … 215 nm (6.5 … 5.77 eV) by mixing the THG with a fundamental wavelength to create the fourth harmonic. The harmonic pulses are of narrow bandwidth nature, enabling a high resolution across the entire tuning range.

The generation of high power tunable UV radiation is based on a widely tunable picosecond OPO with computer controlled tuning, pumped by an industrial high power green laser and with subsequent frequency conversion to reach UV wavelengths below 200 nm.