عنوان
پدید آورنده
موضوع
رده
کتابخانه
محل استقرار
NATIONAL BIBLIOGRAPHY NUMBER
Number
TL1p66d985
LANGUAGE OF THE ITEM
.Language of Text, Soundtrack etc
انگلیسی
TITLE AND STATEMENT OF RESPONSIBILITY
Title Proper
PEROVSKITE AND PEROVSKITE-LIKE MATERIALS FOR SOLUTION-PROCESSED THIN-FILM SOLAR CELLS
General Material Designation
[Thesis]
First Statement of Responsibility
Fabian, David
Subsequent Statement of Responsibility
Ardo, Shane
.PUBLICATION, DISTRIBUTION, ETC
Date of Publication, Distribution, etc.
2018
DISSERTATION (THESIS) NOTE
Body granting the degree
Ardo, Shane
Text preceding or following the note
2018
SUMMARY OR ABSTRACT
Text of Note
Lead-halide-based hybrid organic-inorganic perovskite materials (APbX3) have recently garnered increased attention among researchers worldwide as promising thin-film photovoltaic materials. Laboratory-scale solar cells incorporating APbX3 materials as the light absorber have demonstrated impressive efficiencies of > 20%, but commercialization of solar cells based on solution-cast materials and with only low-temperature processing steps is in-part limited by toxicity and instability of the photoactive materials even under ambient conditions. Specifically, APbX3 contains toxic lead and is not stable in ambient conditions in part because AX dissociates into two water-soluble, low-boiling point species. Therefore, the goal of my doctoral thesis project was to replace the organic monocationic salts in perovskite materials with non-volatile and less water-soluble analogs in the form of organic dicationic salts. Using this rationale, I have demonstrated the use of novel perovskite-like bismuth-halide and copper-halide materials as the photoactive layer in solar cells, which contain hexanediammonium dications (HDA2+) that serve as the organic crystal fastener. I have elucidated structure-property relationships of these and related materials with different organic linkers through measurement of crystal structure, powder and thin-film characterization of the materials, and long-term thermal and moisture stability. I have also studied these materials using ultrafast spectroscopy techniques to elucidate energy-transport and charge-transport dynamics of these materials as thin films. Efficient photovoltaic devices featuring a dicationic metal-halide material that does not contain lead may offer a more environmentally-friendly, stable alternative to the APbX3 photovoltaic devices that currently dominate emerging photovoltaic technology research.
PERSONAL NAME - PRIMARY RESPONSIBILITY
Vincent, Kevin Patrick
PERSONAL NAME - SECONDARY RESPONSIBILITY
Fabian, David
CORPORATE BODY NAME - SECONDARY RESPONSIBILITY
UC Irvine
ELECTRONIC LOCATION AND ACCESS
Electronic name
مطالعه متن کتاب p
[Thesis]
276903
a
Y
