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Nanomaterials made of earth-abundant elements for photovoltaics

Molk, Doreen Fay
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Yang, Yongan
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Date
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2013
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Keywords
photovoltaics
 iron pyrite
 alloying
 nanoparticles
 multijunction
 thin films
 Photovoltaic cells -- Materials
 Nanostructured materials
 Thin films
 Pyrites
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2010-2019 - Mines Theses & Dissertations
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Nanomaterials made of earth-abundant elements for photovoltaics
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https://hdl.handle.net/11124/78771
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Abstract
Of the many types of solar cells currently under exploration, multijunction photovoltaics (MJPVs) are of the most interest due to their record-breaking solar energy conversion efficiencies (over 40%). However, MJPV device fabrication is expensive because they require a costly synthesis technique that utilizes rare elements such as gallium, arsenic, and indium. To resolve this issue, our efforts have been focused on the replacement of the thin-film materials currently employed in MJPVs with a more earth-abundant alternative, Zn-alloyed iron pyrite (Zn<sub>x</sub>Fe<sub>(1-x)</sub>S<sub>2</sub>). The synthesis of Zn<sub>x</sub>Fe<sub>(1-x)</sub>S<sub>2</sub> nanoparticles is of particular interest because a nanoparticle 'ink' can be inserted into a roll-to-roll processor, which is an inexpensive technique of creating defect-free thin-films for electronics. The first part of this work explores the synthesis of Zn-alloyed iron pyrite nanoparticles via the modification of a solvothermal method from the literature. The nanoparticles generated using this method at first indicated zinc-alloying was successful; yet, further studies into the electronic structure of the particles necessitated the addition of a spin-purification step to ensure only highly soluble particles remained for spin-coating deposition. Compositional and structural analysis of the particles that remained after the additional spin-purification step showed evidence of both the ZnS and FeS<sub>2</sub> phases. The second part of this work focuses on the development of an alternative method of generating iron pyrite nanoparticles, which would also eventually be used for zinc-alloying. The two approaches focused on are a hydrothermal method in an acid-digestion bomb and a non-injection solvothermal method in an inert environment. The synthesized particles using these methods were phase-pure and did not contain any detectable quantity of other iron sulfides.
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