Add to ORKGRear-passivated solar cells demonstrate higher efficiency due to reduced rear surface recombination; however surface passivation and patterning methods used need to be robust, capable of high throughput and readily incorporated in production lines. This thesis examined possible cost-effective improvements in rear local contact formation for silicon solar cells that could be used in manufacturing, with a special focus on the formation of anodic oxide dielectric layers and patterning of these layers. An initial study explored the effects of patterning by laser and chemical etching on the properties of local back surface fields (LBSF) regions formed by aluminium alloying. Chemical etching resulted in 2 - 3 µm thicker LBSF regions and reduced K...
In this study, thermal atomic layer deposition (ALD) of Al2O3 is (1) first characterized as surface ...
AbstractThis paper presents a detailed analysis of point-contacted aluminium rear side for silicon s...
2nd International Conference on Crystalline Silicon Photovoltaics (SiliconPV), IMEC, Leuven, BELGIUM...
AbstractLocal rear metal contacting through passivating dielectric layers has the ability to increas...
Surface passivation and metallisation patterning have been the main drivers for continuous cell effi...
Implementation of silicon nitride into the fabrication process of commercial silicon solar cells was...
We investigate the versatility of anodically grown silicon dioxide (SiO2) films in the context of pr...
Tunnel silicon oxides form a critical component for passivated contacts for silicon solar cells. The...
AbstractWet chemical anodic oxides may represent an alternative way of forming passivating dielectri...
In this work, aluminum oxide films with excellent passivation effects were prepared on the rear-side...
We present a detailed study on the rear contact formation of rear-surface-passivated silicon solar c...
We present a comprehensive study on the rear contact formation of rear surface-passivated silicon so...
We investigate the versatility of anodically grown silicon dioxide (SiO2) films in the context of pr...
Electronic surface passivation of p-type crystalline silicon by anodic silicon dioxide (SiO2) was in...
This paper introduces a method to manipulate stored charge density and polarity in anodic aluminium ...
In this study, thermal atomic layer deposition (ALD) of Al2O3 is (1) first characterized as surface ...
AbstractThis paper presents a detailed analysis of point-contacted aluminium rear side for silicon s...
2nd International Conference on Crystalline Silicon Photovoltaics (SiliconPV), IMEC, Leuven, BELGIUM...
AbstractLocal rear metal contacting through passivating dielectric layers has the ability to increas...
Surface passivation and metallisation patterning have been the main drivers for continuous cell effi...
Implementation of silicon nitride into the fabrication process of commercial silicon solar cells was...
We investigate the versatility of anodically grown silicon dioxide (SiO2) films in the context of pr...
Tunnel silicon oxides form a critical component for passivated contacts for silicon solar cells. The...
AbstractWet chemical anodic oxides may represent an alternative way of forming passivating dielectri...
In this work, aluminum oxide films with excellent passivation effects were prepared on the rear-side...
We present a detailed study on the rear contact formation of rear-surface-passivated silicon solar c...
We present a comprehensive study on the rear contact formation of rear surface-passivated silicon so...
We investigate the versatility of anodically grown silicon dioxide (SiO2) films in the context of pr...
Electronic surface passivation of p-type crystalline silicon by anodic silicon dioxide (SiO2) was in...
This paper introduces a method to manipulate stored charge density and polarity in anodic aluminium ...
In this study, thermal atomic layer deposition (ALD) of Al2O3 is (1) first characterized as surface ...
AbstractThis paper presents a detailed analysis of point-contacted aluminium rear side for silicon s...
2nd International Conference on Crystalline Silicon Photovoltaics (SiliconPV), IMEC, Leuven, BELGIUM...