Recently, considerable progress is achieved in lab prototype perovskite solar cells (PSCs); however, the stability of outdoor applications of PSCs remains a challenge due to the high sensitivity of perovskite material under moist and ultraviolet (UV) light conditions. In this work, the UV photostability of PSC devices is improved by incorporating a photon downshifting layer—SrAl2O4: Eu2+, Dy3+ (SAED)—prepared using the pulsed laser deposition approach. Light‐induced deep trap states in the photoactive layer are depressed, and UV light‐induced device degradation is inhibited after the SAED modification. Optimized power conversion efficiency (PCE) of 17.8% is obtained through the enhanced light harvesting and reduced carrier recombination provided by SAED. More importantly, a solar energy storage effect due to the long‐persistent luminescence of SAED is obtained after light illumination is turned off. The introduction of downconverting material with long‐persistent luminescence in PSCs not only represents a new strategy to improve PCE and light stability by photoconversion from UV to visible light but also provides a new paradigm for solar energy storage.
Activated semi-coke, an economical
carbonaceous material, is employed
in the removal of SO2 from simulated flue gas of an industrial
power plant. Activation by four commonly used agents, including CO2, KOH, ZnCl2, and H3PO4,
is studied in detail, which demonstrates that the sample treated with
KOH at high temperature presents the best performance on removal of
SO2. Further investigation on the physical and chemical
properties reveals that both optimized pore structure and increased
amount of active sites of activated semi-coke could contribute to
the high desulfurization capacity. The semi-coke activated with KOH
is selected to discuss possible mechanisms of the adsorption and desorption
processes. Performances with variation of desulfurization temperatures
evidence that physically adsorbed SO2 can transform into
chemically adsorbed SO2, which is significantly affected
by temperature. Desulfurization behaviors under different flue gas
compositions show that oxidation of SO2 to SO3 plays a key role in SO2 removal. By the analyzing desorption
behavior of the samples, a reactive intermediate, C(O) complex, is
proposed to be generated by dissociated chemisorption of O2 onto the surface of activated semi-coke, which serves as the dominating
active site in oxidation of SO2. Besides, activated semi-coke
exhibits several favorable properties in this study that could offer
the prospect for further application in industrial desulfurization.
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