![]() Splinching, though serious, is not fatal, so the body parts are presumably still connected in some way to the Splinched person. This suggests a connection to the concept of Splinching, where a person who incorrectly Apparates leaves some body parts behind. For example, a mouse made to Vanish incompletely will then exist simply as a wriggling tail. This does seem to fit for most circumstances, but there are a few twists. McGonagall states that Vanished objects go “nto non-being, which is to say, everything” ( DH30). The intent of the caster provides the needed focus on a particular object. The Evanesco spell apparently doesn’t need an object word (you don’t have to say “Evanesco Potion,” for example). Taught in fifth year Transfiguration ( OP13), this spell is usually cast using the incantation Evanesco which is Latin for “vanish.” McGonagall starts students out with Vanishing invertebrates-snails-and then works them up to mice because they’re more difficult ( OP15). ![]() The basic form of Vanishing is the Vanishing Spell. 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.Various types of spells and items make things vanish, but in different ways. ![]() 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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