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Index 433 AES:Eu2+ (AE1⁄4Ca and Sr) phosphors, 63, 64f Sr8Al12O24S2:Eu2+ phosphors, 64, 65f synthesis methods halides, 87–88 (oxy)nitrides, 82–86 oxides, 78–82 sulfides, 86–87 surface mount device (SMD) white-light LED package, 88, 88f synthesis procedure, 103 wafer-level packaging (WLP), 92 Luminous efficacy of radiation (LER), 8 M Magmatic crystallization and enrichment accumulation, 154 fractional crystallization, 155–156 immiscibility, 155 Mean field theory, 299 Metal-insulator transitions (MIT), 328 Metal-organic frameworks (MOFs) absolute sensitivity, 396 advantage, 395 postfunctionalization method, 396–397 ratiometric mixed lanthanide-organic dye thermometers, 396 self referencing thermometers, 395–396 Mineral–melt partition coefficients distribution, 137–138, 137f geochemical earth reference model (GERM), 137–138 partitioning coefficients, 136–138 Mineralogy crystal chemistry, ABO4 minerals monazite structure, 168–172t, 174f, 175t, 178f, 179–187, 180f thorium and uranium content, 167, 168–172t zircon structure, 168–172t, 174f, 175–176t, 177–179, 177f earth evolution allanite-(Ce) samples, 182–183, 184f calc-alkaline granitic rocks, 182–183 chondrite-normalized concentration, 182–183, 185f eras and stages, 179–181, 181t Great Oxidation Event (GOE), 182 magnetite- and ilmenite-series magmas, 182–183 monazite, 184–187, 186f zircon, 183–184, 186f MnSi, 328 Molecular thermometers advantage, 388–389 inorganic matrices, 392 organic-inorganic hybrid matrices diureasil hybrid framework, 394 mechanical properties, 393–394 temperature mapping, 394 temperature pseudocolor map, 394, 395f polymer matrices b-diketonates, 389 biomedical applications, 391 dual-center emitters, 390–391 multisensor NPs applications, 390–391, 391f nanothermometer and nanoheater, 391–392, 393f N Nephelauxetic effect, 15 NIR-emitting nanoparticles, 401f, 402 (Oxy)nitrides blue-emitting phosphors, 45–46, 46f green-emitting phosphors AESi2O2N2:Eu2+ (AE1⁄4Ca, Sr, and Ba), 48–51, 49t, 49–50f, 51t b-SiAlON:Eu2+, 46–48, 47–48f Y4Si2O7N2:Ce3+, 51–54, 52f, 52–53t, 54f red-emitting phosphors AE2Si5N8:Eu2+ (AE1⁄4Ca, Sr, and Ba), 57–58, 58t, 59–61f CaAlSiN3:Eu2+, 54–56, 55–57f SrAlSi4N7:Eu2+, 59–63, 61–62f, 62t synthesis methods carbothermal reduction and nitridation, 84–85 gas phase reduction and nitridation, 84 host materials, 82 metallic raw materials, 85–86 nitride raw materials, 82–83 solid-state reaction, 83–84 yellow-emitting phosphors CaAlSiN3:Ce3+, 41–43, 42–43f Ca-a-SiAlON:Eu2+, 40–41, 40–42f La3Si6N11:Ce3+, 44–45, 44–45f Non-Fermi liquid (NFL) Ce(Cu,Au)6, 311 Hertz-Millis theories, itinerant magnets, 302 YbRh2Si2, 311PDF Image | HANDBOOK ON THE PHYSICS AND CHEMISTRY OF RARE EARTHS
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