LuQY Pro

The Absolute Luminescence Quantum Yield System to calculate EL / PLQY & iVoc

When developing opto-electronic devices, such as LEDs or solar cells, it is essential to improve their radiative efficiency. This requires precise techniques to determine the luminescence quantum yield. The LuQY Pro is an easy-to-use, non-invasive and versatile system with unparalleled compactness to swiftly quantify the EL / PLQY and iVOC (QFLS) of thin film absorbers, layer stacks or complete devices under various operating conditions.

LuQY Pro System & Layout

  • Swift quantification of Absolute Photon Fluxes from electro- and photoluminescence (EL & PL) of semiconductor thin films & devices

  • USB-“Plug & Play”: the included software records emission spectra & directly calculates EL/PL Quantum Yield  (PLQY) & implied Voc (iVoc)

  • Small & Portable Layout allows flexible usage e.g. in gloveboxes

One-Click Measurements EL / PLQY

  • Absolute number of photons from steady-state EL/PL spectra (550–1050 nm)

  • Automated, continuously adjustable laser intensity from 0.001-10 “Suns”
  • Current/voltage biasing and sensing via integrated source & measure unit (SMU)
  • EL / PLQY sensitivity range: 1E-4 %

Technical visualization of a measurement system for EL / PLQY
Image of an interface with a graph displaying calculation of EL / PLQY

Software

  • Absolute photon flux measurement
    Records single or multiple EL/PL spectra for pre-set laser intensity, voltage & current bias

  • Immediate calculation of EL / PLQY & iVoc
  • Automated measurement sweeps
    Varies laser intensity, bias voltage & current and determines absolute PL/EL spectra, EL/PLQY and iVoc at each operating point

Applications

Image with a diagram displaying Accelerated Material and Process Parameters

Quality Assessment

Quality assessment for rapid Process Control after each fabrication step or for Accelerated Material and Process Parameter Screenings.

Image with a diagram displaying Emission Spectrum & Intensity as well as EL/PLQY and iVoc

Transient Effects

Fast Acquisition resolves Shifts in Emission Spectrum & Intensity as well as EL / PLQY and iVoc on timescales from 10 ms to several hours.

Image with a diagram displaying Quantifyed Bulk and Interface Recombination Losses

Resolve Bulk & Interface Recombination

Quantifying Bulk and Interface Recombination Losses in semiconductor thin films, layer stacks or complete devices such as solar cells or LEDs. Examples in academic publications can be found in [1-6].

image of diagram displaying bias-Voltage Dependent EL / PLQY & iVoc

Efficiency Potentials & Loss Mechanisms

In-depth analysis of efficiency potentials and loss mechanisms in semiconductor thin films, layer stacks or complete devices, e.g. by determining Ideality Factors and Pseudo-JV Curves from Intensity and/or Bias-Voltage Dependent EL / PLQY & iVoc. Also see [7-9]

Technical Specifications

Current-voltage source and measure unit (SMU) max. ratings

+/-10 V, +/-150 mA

Max. sample dimensions (L x W, unrestricted height)

30 x 30 mm

Max. no. of contactable subcells on sample by integrated relais box

6 subcells

Photoexcitation intensity (continuously adjustable)

0.001 – 10 “Suns”

Photoexcitation wavelength

532 nm

Photoexcitation spot size (interchangeable)

0.1 cm² / 1 cm²

Spectral detection range

550 – 1050 nm

Quantum yield sensitivity range

10-4 – 100%

Corresponding min. resolvable iVoc for 1.6 eV absorber band gap

1.0 V

Spectrometer integration time

1 ms – 65 s

Dimensions (L x W x H)

220 x 275 x 120 mm³

Weight

4.7 kg

Connectors

1x DC, 1x USB 3.0

References

References marked with ‡ indicate publications with contributions from members of our team.

Resolving bulk and interface recombination losses from PLQY and absolute PL:

[1]‡ Unold et al., Advanced Characterization Techniques for Thin Film Solar Cells, Chapter 7: Photoluminescence Analysis of Thin-Film Solar Cells, Wiley, 2011, ISBN: 9783527410033

[2]‡ Al-Ashouri et al., Energy Environ. Sci., 2019, 12, 3356-3369

[3]‡ Kegelmann et al., ACS Appl. Mater. Interfaces, 2019, 11, 9, 9172-9181

[4]‡ Stolterfoht et al., Energy Environ. Sci., 2019, 12, 2778-2788

[5]‡ Liu et al., ACS Energy Lett., 2019, 4, 1, 110-117

[6]‡ Kirchartz et al., Adv. Energy Mater., 2020, Early View 1904134.

Ideality factor and pseudo-JV curves from light-intensity dependent absolute PL:

[7]‡ Caprioglio et al., Adv. Energy Mater., 2019, 9, 33, 110-117

[8]‡ Stolterfoht et al., Adv. Mater., 2020, DOI: 10.1002/adma.202000080

[9] Chris Dreessen et al., Journal of Luminescence, 2020, 222, 117106

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