Post on 01-Apr-2015
Experimental and modelling studies for the growth of high quality silicon-germanium absorber layer for multi-junction
solar cell by RF magnetron co-sputtering system
SEYED AHMAD SHAHAHMADIP64797
Solar Energy Research Institute (SERI)Universiti Kebangsaan Malaysia
Supervisor: Prof. Dr. Nowshad AminProf Dato’ Dr Kamaruzzaman Sopian
Presentation Outline
1. Introduction
2. Problem Statement
3. Research Objectives
4. Methodology
5. Result and Discussion
6. Conclusion
7. Future Work and Grant Chart
Introduction: Triple-junction technology
Thin-film Si solar cells have received attention due to:
• The abundance of raw materials.• Low temperature coefficient.• Low-cost manufacturing.
Despite the many advantages of thin-film Si solar cells, their low efficiencies still present a challenge that must be overcome.
The efficiency of a single-junction amorphous Si solar panel is only 8–9%. Sanyo Solar has demonstrated the stabilized module efficiency up to 12.2% by using double-junction technology (a-Si:H/uc-Si:H). However, a module efficiency of 13% is necessary to be competitive with other solar cell technologies. Triple-junction solar cells offer an even more efficient utilization of the solar spectrum by incorporating thin component cells.
High performance cellsTo obtain the highest cell efficiency, the component cells of a triple-junction structure must be individually optimized.
Recently, Prof. Konagai s group has calculated the theoretical ′conversion efficiencies for triple-junction thin-film Si solar cells. These theoretical efficiencies were obtained by varying the bandgaps of the top and middle cells while fixing that of the Bottom cell at 1.1eV, corresponding to the bandgap of the bottom cell in a μc-Si:H system.
The highest conversion efficiency of 21.4% was obtained when the bandgaps of the top and middle cells were 2 and 1.45 eV, respectively.
Key features:
• Hydrogen dilution during intrinsic (i) layer growth.• Band-gap profiling in a-SiGe:H intrinsic layers.• Optimum matching of the component.• Highly conductive tunnel junctions.• Highly reflective textured back reflectors and quality of the
textured TCO.• Continuous deposition process.• Enhancement in current matching (intermediate reflector layers)
Top Cell (a-Si:H/a-SiC:H)
Middle Cell (uc-Si:H/ nc-Si:H/ a-SiGe:H)
Bottom Cell (uc-Si:H/ nc-Si:H/ uc-SiGe:H)
Introduction: Silicon Germanium solar cells
Structure Configuration Initial Eff (%) Final Eff (%) Reporting laboratory and references
Single-junction uc-SiGe:H 5.3 Tianjin Key Laboratory (2013)
Single-junction uc-SiGe:H 5.5 National Chiao Tung University (2012)
Single-junction a-SiGe:H 11.18 LG (2013)
Single-junction a-SiGe:H 8.26 Beijing Key Laboratory (2013)
Single-junction a-SiGe:H 5.93 ETRI
Single-junction a-SiGe:H 8.59 National Chiao Tung University (2012)
Single-junction a-SiGe:H 8.64 NREL (2009)
Single-junction a-SiGe:H 6.38 ITRI
Double-junction a-Si:H/a-SiGe:H 11.8 Tianjin Key Laboratory (2013)
Double-junction a-Si:H/uc-SiGe:H 11.2 AIST (2012)
Triple-junction a-Si:H/a-SiGe:H/uc-SiGe:H 12.02 Tianjin Key Laboratory (2013)
Triple-junction a-Si:H/a-SiGe:H/a-SiGe:H 9.89 Beijing Key Laboratory (2012)
Triple-junction a-Si:H/a-SiGe:H/a-SiGe:H 14.6 United Solar (1997)
Triple-junction a-Si:H/a-SiGe:H/uc-Si:H 16.1 13.44 LG (2013)
Triple-junction a-Si:H/a-SiGe:H/nc-Si:H 16.3 United Solar (2011)
Triple-junction a-Si:H/a-SiGe:H/nc-Si:H 15.2 LGE (2012)
Triple-junction a-Si:H/a-SiGe:H/nc-Si:H 13.3 United Solar (2005)
Table: 1 Selected results of small area
Problem Statement
Expanding the absorption of the sun light by Silicon-Germanium via reduced band gap.
Research Objectives
1. To design an optimized high efficiency SiGe thin film solar cell structure using SCAPS and ATLAS computer simulation for experimental validation.
2. To fabricate SiGe thin film absorber layers by co-sputtering technique.
3. To investigate the effects of deposition profile (temperature, power and pressure) on the electrical, optical, structural and morphological properties of SiGe absorber layer and subsequently identify the optimum deposition profile.
4. To achieve high photovoltaic conversion efficiency through optimization of SiGe Single-junction solar cell.
Experimental details
Condition of SixGe1-x (0.550.02) films sputtering
Substrate Soda lime glass
Power Si: 50 w / Ge: 25 w
Base pressure 5e-5 Torr
Substrate temperature RT,300,350,400,450,500
Argon flow rate 3 sccm
Thickness 3006% nm
Result & Discussion: FESEM
a-SiGe RT a-SiGe 350 C
a-SiGe 500 C
Result & Discussion: Raman & XRD
Result & Discussion: UV-VIS-IR
1 1.1 1.2 1.3 1.4 1.5 1.60
0.1
0.2
0.3
0.4
0.5
0.6
0.7
a-SiGe
Band-gap: 1.1 eV
Conclusion
• Field Emission Scanning Electron Microscopy (FESEM) also disclosed forming of grains in high temperature.
• crystallinity of the films were improved by increasing temperature above nucleus point of material in the high level of base pressure 5 × 10-5 Torr.
• Optical band gaps of these films derived from Tauc plots (1.1 eV), which were calculated from reflectance/transmittance measurements.
Future Work
1. The gradual improvement of stress type (tensile to compressive) of the SiGe films is subject to further detailed investigation (Temperature and pressure).
2. In order to have investigation on Hall measurement, thicker films have to be prepared.
3. n and p materials should be chosen to make optimum absorber layer.
Research timeline
Feb 2012
I’m here
Feb 2015Feb 2014Feb 2013
3 6 9 12 15 18 21 24 27 30 33 36
To design an optimized high efficiency SiGe thin film solar cell structure using SCAPS and ATLAS computer simulation for experimental validation.
To fabricate SiGe thin film absorber layers by co-sputtering technique.
To investigate the effects of deposition profile (temperature, power and pressure) on the electrical, optical, structural and morphological properties of SiGe absorber layer and subsequently identify the optimum deposition profile.
To achieve high photovoltaic conversion efficiency through optimization of SiGe Single-junction solar cell.
Final thesis
I’m here
Thank You
Q & A