TY - JOUR
T1 - Hackmanite - The Natural Glow-in-the-Dark Material
AU - Agamah, Cecilia
AU - Vuori, Sami
AU - Colinet, Pauline
AU - Norrbo, Isabella
AU - de Carvalho, José Miranda
AU - Nakamura, Liana Key Okada
AU - Lindblom, Joachim
AU - van Goethem, Ludo
AU - Emmermann, Axel
AU - Saarinen, Timo
AU - Laihinen, Tero
AU - Laakkonen, Eero
AU - Linden, Johan
AU - Konu, Jari
AU - Vrielinck, Henk
AU - Van der Heggen, David
AU - Smet, Philippe
AU - Le Bahers, Tangui
AU - Lastusaari, Mika
N1 - Ganska många författare, ids inte knappa in dem en och en.....: Agamah, Cecilia; Vuori, Sami; Colinet, Pauline; Norrbo, Isabella; de Carvalho, JoséMiranda; Okada, Nakamura, Liana Key; Lindblom, Joachim; van Goethem, Ludo;Emmermann, Axel; Saarinen, Timo; Laihinen, Tero; Laakkonen, Eero; Lindén,Johan; Konu, Jari; Vrielinck, Henk; Van der Heggen, David; Smet, Philippe F.;Bahers, Tangui, Le; Lastusaari, Mika
PY - 2020/9/25
Y1 - 2020/9/25
N2 - “Glow-in-the-dark” materials are known to practically everyone who has ever traveled by airplane or cruise ship, since they are commonly used for self-lit emergency exit signs. The green afterglow, persistent luminescence (PeL), is obtained from divalent europium doped to a synthetic strontium aluminate, but there are also some natural minerals capable of afterglow. One such mineral is hackmanite, the afterglow of which has never been thoroughly investigated, even if its synthetic versions can compete with some of the best commercially available synthetic PeL materials. Here we combine experimental and computational data to show that the white PeL of natural hackmanite is generated and controlled by a very delicate interplay between the natural impurities present. The results obtained shed light on the PeL phenomenon itself thus giving insight into improving the performance of synthetic materials.
AB - “Glow-in-the-dark” materials are known to practically everyone who has ever traveled by airplane or cruise ship, since they are commonly used for self-lit emergency exit signs. The green afterglow, persistent luminescence (PeL), is obtained from divalent europium doped to a synthetic strontium aluminate, but there are also some natural minerals capable of afterglow. One such mineral is hackmanite, the afterglow of which has never been thoroughly investigated, even if its synthetic versions can compete with some of the best commercially available synthetic PeL materials. Here we combine experimental and computational data to show that the white PeL of natural hackmanite is generated and controlled by a very delicate interplay between the natural impurities present. The results obtained shed light on the PeL phenomenon itself thus giving insight into improving the performance of synthetic materials.
U2 - 10.1021/acs.chemmater.0c02554
DO - 10.1021/acs.chemmater.0c02554
M3 - Article
SN - 0897-4756
VL - 32
SP - 8895
EP - 8905
JO - Chemistry of Materials
JF - Chemistry of Materials
IS - 20
ER -