Also in the story Babbitty Rabbitty and her Cackling Stump in the same book, the witch Babbitty Rabbity successfully vanished a hat. In The Wizard and the Hopping Pot from The Tales of Beedle the Bard, the son of the original owner of the pot tried to vanish the pot, but the spell had no effect. For example, Fred and George Weasley charmed their Weasleys' Wizard Wheezes fireworks so that if anyone attempted to Vanish them, not only would they remain but would multiply by ten each time would so occurs. Ĭertain objects could be enchanted to resist Vanishing Spells, such as fireworks. Minerva McGonagall stated that Vanished objects went " into non-being, which was to say, everything". The greatest challenge, however, was the vanishment of a kitten, which Hermione Granger managed to do by mid-year. It became more difficult with the complexity of the animal to be vanished for instance, a snail, as an invertebrate, was rather simple, whereas the mouse, as a mammal, presented a great challenge. Sirringhaus†, Two-Dimensional Carrier Distribution in Top-Gate Polymer Field-Effect Transistors: Correlation between Width of Density of Localized States and Urbach Energy, Advanced Materials, 26, 728–733, 2014.DOI: 10.1002/adma.The Vanishing Spell was one of the most complicated spells taught at Ordinary Wizarding Level (A.K.A. Sirringhaus†, Approaching Disorder-Free Transport in High-Mobility Conjugated Polymers, Nature, 515, 384–388, 2014. Sirringhaus†, Scanning Kelvin Probe Microscopy Investigation of the Role of Minority Carriers on the Switching Characteristics of Organic Field-Effect Transistors, Advanced Materials, 28, 4713–4719, 2016. Sirringhaus†*, Trap Healing for High-Performance Low-Voltage Polymer Transistors and Solution-Based Analog Amplifiers on Foil, Advanced Materials, 29, 1606938, 2017. Sirringhaus, Inkjet Printed Nanocavities on a Photonic Crystal Template, Advanced Materials, 29 (47), 1704425, 2017. Pecunia†*, Efficiency and Spectral Performance of Narrowband Organic and Perovskite Photodetectors: a Cross-Sectional Review, Journal of Physics: Materials, 2, 042001, 2019. Li, Perovskite-Inspired Lead-Free Ag2BiI5 for Self-Powered NIR-Blind Visible Light Photodetection, Nano-Micro Letters, 12:27, 2020. Pecunia†*, Microstructural and Photoconversion Efficiency Enhancement of Compact Films of Lead-Free Perovskite Derivative Rb3Sb2I9, Journal of Materials Chemistry A, 8, 4396–4406, 2020. Pecunia†*, Narrowband-Absorption-Type Organic Photodetectors for the Far-Red Range Based on Fullerene-Free Bulk Heterojunctions, Advanced Optical Materials, 1902056, 2020. Pecunia†*, Enhanced photoconversion efficiency in cesium-antimony-halide perovskite derivatives by tuning crystallographic dimensionality, Applied Materials Today, 19, 100637, 2020. Pecunia†*, Ambipolar Deep-Subthreshold Printed-Carbon-Nanotube Transistors for Ultralow-Voltage and Ultralow-Power Electronics, ACS Nano, 14, 10, 14036–14046, 2020. Peng, Lead-Free Halide Perovskite Photovoltaics: Challenges, Open Questions and Opportunities, APL Materials, 8(10), 100901, 2020. Hoye†, V.Pecunia†, Lead-Free Perovskite-Inspired Absorbers for Indoor Photovoltaics, Advanced Energy Materials, 11(1), 2002761, 2021. Sirringhaus, Assessing the Impact of Defects on Lead-Free Perovskite-Inspired Photovoltaics via Photo-Induced Current Transient Spectroscopy, Advanced Energy Materials, 11(22), 2003968, 2021. Hoye†, Emerging Indoor Photovoltaic Technologies for Sustainable Internet of Things, Advanced Energy Materials, 2100698, 2021. Pecunia*†, Two-Dimensional Antimony-Based Perovskite-Inspired Materials for High-Performance Self-Powered Photodetectors, Advanced Functional Materials, 2106295, 2021.
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