Thin–Film Crystalline Silicon Solar Cells – Physics and Technology

Rolf Brendel studied Physics and Mathematics in Freiburg, Brighton (UK), and Heidelberg. After his Ph.D. in materials science at the University Erlangen Nuremberg he worked for five years with the Max Planck Institute for Solid State Research in Stuttgart. He is the head of the division for Thermosensorics and Photovoltaics at the Bavarian Center for Applied Energy Research (ZAE Bayern) and teaches Physics at the University of Erlangen Nuremberg.

Foreword. Preface. Symbols and Acronyms. INTRODUCTION. Highest efficiency crystalline Si solar cells. Industrial crystalline Si solar cells. Thin film crystalline Si cells. Physical problems with thin film crystal line Si cells. PHYSICAL LOSS MECHANISMS. Limitations to photogeneration. Limitations imposed by radiative recombination. Limitations imposed by non radiative recombination. ADVANCED QUANTUM EFFICIENCY ANALYSIS. Definition of effective diffusion lengths. Reciprocity theorem for charge carrier collection. Applications of the generalized reciprocity theorem. Limiting recombination parameters derived from LQ. Analytical quantum efficiency model for thin films. Differential and actual recombination parameters. TECHNOLOGICAL APPROACHES TO THIN FILM CELLS. High temperature substrate (HTS) approach. Low temperature substrate (LTS) approach. Layer transfer process (LTP) approach. WAFFLE CELLS FROM THE POROUS SI (PSI) PROCESS. Epitaxy on porous Si. ;p> Module concepts. Optical absorption in Si waffles. Efficiency potential. SUMMARY AND CONCLUSIONS. Physical limitations to power conversion. Revealing the limitations of experimental cells. Limitations of current thin film approaches. Porous Si for layer transfer. Update. APPENDICES. Appendix A: Light Trapping. Appendix B: Recombination. Appendix C: Quantum Efficiency. References. Index.