?url_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Adc&rft.title=High+efficiency+quantum+dot-sensitised+solar+cells+by+material+science+and+device+architecture&rft.creator=Rasin%2C+Ahmed+Tasnim&rft.subject=Solar+Cells&rft.subject=Quantum+Dot&rft.subject=Photovoltaic&rft.subject=Quantum+Dot-sensitised+Solar+Cells&rft.subject=Solution-processed+Photovoltaic&rft.subject=Photodegradation&rft.subject=Passivation&rft.subject=Shell+coating&rft.subject=Quantum+confinement&rft.subject=Surface+coverage&rft.description=This+thesis+studied+cadmium+sulfide+and+cadmium+selenide+quantum+dots+and+their+performance+as+light+absorbers+in+quantum+dot-sensitised+solar+cells.+This+research+has+made+contributions+to+the+understanding+of+size+dependent+photodegradation%2C+passivation+and+particle+growth+mechanism+of+cadmium+sulfide+quantum+dots+using+SILAR+method+and+the+role+of+ZnSe+shell+coatings+on+solar+cell+performance+improvement.&rft.publisher=Queensland+University+of+Technology&rft.date=2014&rft.type=Thesis&rft.format=application%2Fpdf&rft.relation=https%3A%2F%2Feprints.qut.edu.au%2F78822%2F1%2FAhmed%2520Tasnim_Rasin_Thesis.pdf&rft.rights=free_to_read&rft.relation=Rasin%2C+Ahmed+Tasnim+(2014)+High+efficiency+quantum+dot-sensitised+solar+cells+by+material+science+and+device+architecture.+PhD+thesis%2C+Queensland+University+of+Technology.&rft.id_number=https%3A%2F%2Feprints.qut.edu.au%2F78822%2F&rft.identifier=Science+%26+Engineering+Faculty%3B+School+of+Chemistry%2C+Physics+%26+Mechanical+Engineering