Diffractive Optics for Thin-Film Silicon Solar Cells

1. Front Matter

   Pages i-xx

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2. Introduction

   • Christian Stefano Schuster

   Pages 1-10

3. Nanostructures for Enhanced Light-Trapping in Thin-Film Silicon Solar Cells

   • Christian Stefano Schuster

   Pages 11-51

4. Fabrication and Characterisation of Diffractive Nanostructures

   • Christian Stefano Schuster

   Pages 53-64

5. Achievements

   • Christian Stefano Schuster

   Pages 65-86

6. Conclusions and Outlook

   • Christian Stefano Schuster

   Pages 87-94

7. Back Matter

   Pages 95-114

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This thesis introduces a figure of merit for light trapping with photonic nanostructures and shows how different light trapping methods compare, irrespective of material, absorber thickness or type of nanostructure. It provides an overview of the essential aspects of light trapping, offering a solid basis for future designs.


Light trapping with photonic nanostructures is a powerful method of increasing the absorption in thin film solar cells. Many light trapping methods have been studied, but to date there has been no comprehensive figure of merit to compare these different methods quantitatively. This comparison allows us to establish important design rules for highly performing structures; one such rule is the structuring of the absorber layer from both sides, for which the authors introduce a novel and simple layer-transfer technique. A closely related issue is the question of plasmonic vs. dielectric nanostructures; the authors present an experimentaldemonstration, aided by a detailed theoretical assessment, highlighting the importance of considering the multipass nature of light trapping in a thin film, which is an essential effect that has been neglected in previous work and which allows us to quantify the parasitic losses. 

• Light Trapping in Nanostructures
• Solar Cell Absorption
• Absorption Enhancement
• Enhanced Light Trapping
• Multi-pass Light Trapping
• Surface Structures
• Surface Textures
• Diffractive Structures
• Diffractive Textures

• Department of Physics, University of York , York, United Kingdom

  Christian Stefano Schuster

Christian Schuster started his studies in physics at Tuebingen (Germany), before continuing at Trento (Italy) with a BSc in nuclear physics. Due to the program being split between two universities, he received a German Diplom in nanotechnology and an Italian MSc in silicon electronics. Christian then moved to St Andrews (UK) to start his PhD project in silicon photonics as a Marie Curie Fellow; he finished this work at York, where he is still based.

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