Passivation Of Nickel Vacancy Defects In Nickel Oxide Solar Cells By Targeted Atomic Deposition Of Boron
JOURNAL OF PHYSICAL CHEMISTRY C(2016)
摘要
Localized trap states, which are deleterious to the performance of many solar-energy materials, often originate from the under-coordinated bonding associated with defects. Recently, the concept of targeted atomic deposition (TAD) was introduced as a process that permits the passivation of trap states using a vapor-phase precursor that selectively reacts with only the surface defect sites. Here, we demonstrate the passivation of nickel oxide (NiO) with the TAD process using diborane gas for selective, low-temperature deposition of boron (B) under continuous flow in a chemical vapor deposition (CVD) system. NiO is a ubiquitous cathode material used in dye-sensitized solar cells (DSSCs), organic photovoltaic devices, and organo-lead halide perovskite solar cells. The deposition of B at 100 C is shown to follow first-order kinetics, exhibiting saturation at a B to Ni atomic ratio of similar to 10%. Electrochemical measurements, combined with first-principles calculations, indicate that B passivates Ni vacancy defects by partially saturating the bonding of the oxygen atoms adjacent to the vacancy. p-Type DSSCs were fabricated using TAD-treated NiO and show a modest improvement in photovoltaic performance metrics. The results highlight the potential ubiquity of TAD passivation with a range of atomic precursors and vapor-phase processes.
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