K-Alpha: Mapping of the Work Function of a Damaged Solar Cell
Applications | 2011 | Thermo Fisher ScientificInstrumentation
Control of surface work function is critical for the performance and reliability of thin film solar cells. Mapping local variations in work function reveals defects such as delamination or compositional inhomogeneities that can impair device efficiency and longevity.
This study demonstrates the use of a Thermo Scientific K-Alpha XPS system to measure and spatially map work function variations across a damaged CIGS solar cell. Three distinct regions created by delamination were targeted to correlate work function values with material identity and damage extent.
Work function measurements were performed by acquiring full-range survey spectra with the Fermi level aligned at zero binding energy via sample bias. Low and high binding energy cut-off positions were extracted and subtracted from the Al Kα photon energy (1486.6 eV). Internal copper, silver and gold standards auto-calibrate the binding energy scale while photon energy verification uses an X-ray induced Auger peak. Mapping employed a 50 μm X-ray spot and principal component analysis algorithms in the Avantage software for rapid spectral processing.
Optical inspection identified three regions: an intact indium tin oxide layer, a silver contact region and a molybdenum back electrode with residual CIGS material. Cut-off analysis via XPS yielded distinct work functions for each region, reflecting their surface composition. Work function maps clearly delineated these areas, validating the correlation between electrical property variations and material identity. Calibration against a gold standard produced a work function value of 5.1 eV, consistent with literature.
Emerging developments may include higher spatial resolution mapping using focused X-ray optics and integration of machine learning for automated defect recognition. Coupling XPS work function mapping with advanced microscopy techniques will further enhance understanding of structure-property relationships in next-generation photovoltaic materials.
The K-Alpha XPS system provides a powerful tool for quantitative work function mapping of damaged solar cell structures, enabling direct correlation between surface composition and electrical properties. Such analyses are invaluable for optimizing manufacturing processes and diagnosing device failures.
Thermo Fisher Scientific Application Note 52078 Mapping of the Work Function of a Damaged Solar Cell
X-ray
IndustriesMaterials Testing
ManufacturerThermo Fisher Scientific
Summary
Importance of Topic
Control of surface work function is critical for the performance and reliability of thin film solar cells. Mapping local variations in work function reveals defects such as delamination or compositional inhomogeneities that can impair device efficiency and longevity.
Objectives and Study Overview
This study demonstrates the use of a Thermo Scientific K-Alpha XPS system to measure and spatially map work function variations across a damaged CIGS solar cell. Three distinct regions created by delamination were targeted to correlate work function values with material identity and damage extent.
Methodology and Instrumentation
Work function measurements were performed by acquiring full-range survey spectra with the Fermi level aligned at zero binding energy via sample bias. Low and high binding energy cut-off positions were extracted and subtracted from the Al Kα photon energy (1486.6 eV). Internal copper, silver and gold standards auto-calibrate the binding energy scale while photon energy verification uses an X-ray induced Auger peak. Mapping employed a 50 μm X-ray spot and principal component analysis algorithms in the Avantage software for rapid spectral processing.
Results and Discussion
Optical inspection identified three regions: an intact indium tin oxide layer, a silver contact region and a molybdenum back electrode with residual CIGS material. Cut-off analysis via XPS yielded distinct work functions for each region, reflecting their surface composition. Work function maps clearly delineated these areas, validating the correlation between electrical property variations and material identity. Calibration against a gold standard produced a work function value of 5.1 eV, consistent with literature.
Benefits and Practical Applications
- Rapid and accurate quantification of work function across heterogeneous surfaces
- Spatial mapping capability supports identification of thin film delamination defects
- Combined electrical and chemical surface analysis aids solar cell quality control and failure investigation
Future Trends and Applications
Emerging developments may include higher spatial resolution mapping using focused X-ray optics and integration of machine learning for automated defect recognition. Coupling XPS work function mapping with advanced microscopy techniques will further enhance understanding of structure-property relationships in next-generation photovoltaic materials.
Conclusion
The K-Alpha XPS system provides a powerful tool for quantitative work function mapping of damaged solar cell structures, enabling direct correlation between surface composition and electrical properties. Such analyses are invaluable for optimizing manufacturing processes and diagnosing device failures.
Reference
Thermo Fisher Scientific Application Note 52078 Mapping of the Work Function of a Damaged Solar Cell
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