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Obtaining efficiently tunable red emission in Ca3-δLnδWO6 : Mn4+ (Ln = La, Gd, Y, Lu, δ = 0.1) phosphors derived from nearly nonluminescent Ca3WO6 : Mn4+ via ionic substitution engineering for solid-state lighting
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Achieving efficient red-emitting Sr2Ca1−δLnδWO6:Mn4+ (Ln = La, Gd, Y, Lu, δ = 0.10) phosphors with extraordinary luminescence thermal stability for potential UV-LEDs application via facile ion substitution in luminescence-ignorable Sr2CaWO6:Mn4+
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A far-red-emitting NaMgLaTeO6:Mn4+ phosphor with perovskite structure for indoor plant growth
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Synthesis and luminescence properties of a novel dazzling red-emitting phosphor NaSr3SbO6:Mn4+ for UV/n-UV w-LEDs
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Mutual energy transfer luminescent properties in novel CsGd(MoO4)2:Yb3+,Er3+/Ho3+ phosphors for solid-state lighting and solar cells
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Realizing a novel dazzling far-red-emitting phosphor NaLaCaTeO6:Mn4+with high quantum yield and luminescence thermal stabilityviathe ionic couple substitution of Na++ La3+for 2Ca2+in Ca3TeO6:Mn4+for indoor plant cultivation LEDs
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Novel intense emission-tunable Li1.5La1.5WO6:Mn4+,Nd3+,Yb3+ material with good luminescence thermal stability for potential applications in c-Si solar cells and plant-cultivation far-red-NIR LEDs
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Insight into emission-tuning and luminescence thermal quenching investigations in NaLa1−xGdxCa4W2O12:Mn4+ phosphors via the ionic couple substitution of Na+ + Ln3+ (Ln = La, Gd) for 2Ca2+ in Ca6W2O12:Mn4+ for plant-cultivation LED applications
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Stabilizing fluoride phosphors : surface modification by atomic layer deposition
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Eu3+/Sm3+ -doped Na2BiMg2(VO4)3 from substitution of Ca2+ by Na+ and Bi3+ in Ca2NaMg2(VO4)3 : color-tunable luminescence via efficient energy transfer from (VO4)3- to Eu3+/Sm3+ ions