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Transition Metal-Involved Photon UpconversionIn-situ Electric Field-Induced Modulation of Photoluminescence in Pr-doped Ba0.85Ca0.15Ti0.90Zr0.10O3 Lead-Free CeramicsRare Earth Nanoprobes for Functional Biomolecular Imaging and Theranostics.Alkalicyamelurates, M3[C6N7O3].xH2O, M = Li, Na, K, Rb, Cs: UV-luminescent and thermally very stable ionic tri-s-triazine derivatives.Synthesis, mesomorphism, and unusual magnetic behaviour of lanthanide complexes with perfluorinated counterions.The characteristic red chemiluminescence from reactions with acidic potassium permanganate: further spectroscopic evidence for a manganese(II) emitter.Defect-mediated photoluminescence dynamics of Eu3+-doped TiO2 nanocrystals revealed at the single-particle or single-aggregate level.Recent developments in the field of inorganic phosphors.Quantum effect on the energy levels of Eu2+ doped K2Ca2(SO4)3 nanoparticles.Facile synthesis of an up-conversion luminescent and mesoporous Gd2O3 : Er3+@nSiO2@mSiO2 nanocomposite as a drug carrier.Tuning of near-infrared luminescence of SrTiO3:Ni2+ thin films grown on piezoelectric PMN-PT via strain engineeringMorphology- and size-dependent spectroscopic properties of Eu(3+)-doped Gd2O3 colloidal nanocrystals.A Strategy to enhance Eu3+ emission from LiYF4:Eu nanophosphors and green-to-orange multicolor tunable, transparent nanophosphor-polymer composites.Synthesis and spectral investigations of Cu(II) ion-doped NaCaAlPO4 F3 phosphor.Lanthanide-to-lanthanide energy-transfer processes operating in discrete polynuclear complexes: can trivalent europium be used as a local structural probe?Tuning oxygen vacancy photoluminescence in monoclinic Y2WO6 by selectively occupying yttrium sites using lanthanum.Down-shifting and upconversion photoluminescence in Ho(3+)/Yb(3+) codoped GdNbO4: effect of the Bi(3+) ion and the magnetic field.Silver nanowires as receiving-radiating nanoantennas in plasmon-enhanced up-conversion processes.Faraday rotation and photoluminescence in heavily Tb(3+)-doped GeO2-B2O3-Al2O3-Ga2O3 glasses for fiber-integrated magneto-optics.UVB-emitting Gd(3+)-activated M2O2S (where M = La, Y) for phototherapy lamp phosphors.Infrared and visible emissions of rare-earth-doped CeO2 phosphor.Luminescence studies on SnO2 and SnO2:Eu nanocrystals grown by laser assisted flow deposition.Synthesis of Gd2O3:Eu nanoplatelets for MRI and fluorescence imaging.Intense NIR emissions at 0.8 μm, 1.47 μm, and 1.53 μm from colloidal LiYbF4:Ln(3+) (Ln = Tm(3+) and Er(3+)) nanocrystals.Direct observation of the core/double-shell architecture of intense dual-mode luminescent tetragonal bipyramidal nanophosphors.Controlling the Two-Photon-Induced Photon Cascade Emission in a Gd(3+)/Tb(3+)-Codoped Glass for Multicolor Display.Tens of micron-sized unilamellar nanosheets of Y/Eu layered rare-earth hydroxide: efficient exfoliation via fast anion exchange and their self-assembly into oriented oxide film with enhanced photoluminescence.Tailored Near-Infrared Photoemission in Fluoride Perovskites through Activator Aggregation and Super-Exchange between Divalent Manganese Ions.Effect of Mg doping in Sr2 SiO4 :Eu2+ nanophosphors for blue and white emission at near-UV excitation.Utilization of native oxygen in Eu(RE)-doped GaN for enabling device compatibility in optoelectronic applications.MgO:Li,Ce,Sm as a high-sensitivity material for Optically Stimulated Luminescence dosimetry.Luminescence and luminescence quenching of highly efficient Y2Mo4O15:Eu(3+) phosphors and ceramicsNear-infrared luminescent CaTiO3:Nd(3+) nanofibers with tunable and trackable drug release kinetics.Sulfate Exchange of the Nitrate-Type Layered Hydroxide Nanosheets of Ln2(OH)5NO3·nH2O for Better Dispersed and Multi-color Luminescent Ln2O3 Nanophosphors (Ln = Y0.98RE0.02, RE = Pr, Sm, Eu, Tb, Dy, Ho, Er, and Tm)Linear structural evolution induced tunable photoluminescence in clinopyroxene solid-solution phosphorsThe development of Ce3+-activated (Gd,Lu)3Al5O12 garnet solid solutions as efficient yellow-emitting phosphors.Ultrasensitive Luminescent In Vitro Detection for Tumor Markers Based on Inorganic Lanthanide Nano-Bioprobes.Lanthanide-containing light-emitting organic-inorganic hybrids: a bet on the future.Lanthanide-doped hollow nanomaterials as theranostic agents.How to produce white light in a single-phase host?
P2860
Q28817386-574CE008-EC28-463F-8429-FADF53D60065Q28829067-CFD92886-D8C2-4312-B147-716BC00A2779Q30410841-2D18CDCF-7BF1-4081-BA81-6B56CCAEC4AEQ30975965-119FE326-03B7-4C15-8E87-7A643FCD5DC4Q32012741-07CD0E9F-B7FE-496E-831C-9A811CDB7A2EQ33310954-B8DC2497-AA05-4CE0-B212-4502B4B27411Q33343201-D014F3A2-2078-4A7C-B2FC-6CFC507BF196Q33427481-CD400800-D5D5-40B3-B86B-7D2313141736Q33553571-BC3601E5-09EC-4F77-90EB-7D0B7806B57FQ33754802-09C64A5C-32F8-4046-9F30-A22BF9495915Q33912571-5FCD1222-C164-4634-8403-9260E01D64FDQ34363423-AEFC8E78-E03D-4863-9239-9E9A0B33FDABQ34981085-02DEB821-DCF1-4823-8BA1-1EE7A572466AQ35158380-729F03E7-3D5D-48A8-AA62-4549866C2751Q35220515-90949C5F-844C-4AFA-A109-E7F443F29AA8Q35227408-EFB90505-E517-449C-B530-F12A18079553Q35259248-E77C1B05-DACE-48EC-8CF9-AA1DE14219EDQ35518125-EBB0E385-BD84-410D-8FFC-EA9D0FEF8CD6Q35574238-72989952-B403-4168-9CE3-854862AD1C73Q35584619-15E112A2-633A-42FD-B2DA-1A517AF2F3BBQ35587069-287A975A-DCBC-4F11-A81D-1CCEEC9D8666Q35620026-73FDC66B-4F4B-4A7E-83CB-5117F619B7A1Q35661682-4506E408-F495-475B-ABA8-E801E9AB6DE9Q35670091-9F428FE5-511B-4DE8-9466-FBE0801852EFQ35884686-539424E6-D80F-4F5E-93F2-1FC99A62915FQ35929894-0B924655-F17D-4ACA-9B9C-306DF9DB8CEBQ36201917-4F2D0AC2-04E6-42E0-AD89-D08089E09621Q36226253-915976EE-332D-4683-B7D9-47EA022CAACEQ36244137-F544A49E-01AF-4301-AD7C-EBDD41BA63E6Q36423418-A3C905AB-C4BD-4745-80BC-A29D7ED70D4BQ36796191-226B8EB6-7B49-4728-93AD-BAD174344F01Q36903174-6E5CD352-2D8D-4851-9C3C-53080017EE3BQ37068226-5D37263D-16DC-4ADF-BC93-1D2189E8297EQ37088751-E72426BC-E0F1-4146-BB99-51D728D3F9BBQ37334348-2457C673-9F32-420C-9534-DF5F5E196200Q37386421-2D68FA46-F42F-4626-BA97-4503C41F0EACQ37404644-933191F7-8D9F-4B9E-B429-45A6D855A163Q37821420-849158EC-92E0-4FF5-B3B2-B548030E109CQ38162427-06BF7806-1575-421E-9816-1FC90CDA8973Q38171979-41C1FAE2-C146-4372-B237-D40D65E97E19
P2860
description
наукова стаття, опублікована в 1994
@uk
name
Luminescent Materials
@en
type
label
Luminescent Materials
@en
prefLabel
Luminescent Materials
@en
P1476
Luminescent Materials
@en
P2093
B. C. Grabmaier
P356
10.1007/978-3-642-79017-1
P577
1994-01-01T00:00:00Z