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June 10, 2026

Why Point Measurements Are Not Enough for Structured Perovskite Devices

Spatially Resolved TRPL for Perovskite Mini Modules

Laser patterning defines the functionality of perovskite solar mini modules, but local photophysical changes are often invisible in conventional point measurements alone.
Spatially resolved TRPL image recorded from sample B, showing photoluminescence intensity distribution along laser-patterned lines. The structured regions remain photoluminescent, indicating that the laser process modifies local photophysical properties rather than completely removing the emissive material.

Revealing Hidden Dynamics in Patterned Perovskites

Perovskite solar mini modules rely on laser-structured regions to define electrically functional areas. While steady-state photoluminescence measurements can confirm the optical response of the active layer, they often provide limited insight into how laser processing affects local recombination dynamics and material properties.

Why Spatially Resolved TRPL Matters

Time-resolved photoluminescence (TRPL) imaging extends conventional TRPL measurements by combining temporal and spatial information across structured regions. This approach enables localized analysis of carrier dynamics and reveals photophysical variations that may remain hidden in point measurements alone.

Spatially resolved TRPL image recorded from sample B, showing photoluminescence intensity distribution along laser-patterned lines. The structured regions remain photoluminescent, indicating that the laser process modifies local photophysical properties rather than completely removing the emissive material.
Spatially resolved TRPL image, showing photoluminescence intensity distribution along laser-patterned lines. The structured regions remain photoluminescent, indicating that the laser process modifies local photophysical properties rather than completely removing the emissive material.

Solira as an Integrated TRPL Platform

Solira was used to combine sample navigation, steady-state spectral characterization, and spatially resolved TRPL imaging within one measurement environment. This makes it possible to correlate where photoluminescence occurs, how it decays over time, and how local carrier dynamics change across laser-patterned regions.

Solira upright time-resolved photoluminescence microscope with motorized sample stage for TRPL imaging and material characterization.
Solira is a time-resolved photoluminescence microscope for advanced materials research.

Download the Application Note

Explore how spatially resolved TRPL imaging was used to investigate laser-patterned perovskite solar mini modules, including spectral characterization, localized decay analysis, and spatial mapping of photoluminescence behavior.

Application Note: Spatially Resolved TRPL Imaging

This application note demonstrates spatially resolved TRPL imaging of laser-patterned perovskite solar mini modules.

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Galaan Merga

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Galaan Merga

Scientific Writer, PicoQuant
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