Energy transfer cooperation between ligands and Eu^III ions in molecular europium complexes for vapoluminescence sensing (reversible on/off emission switching) and hybrid white LED/plant-growth applications

Abstract: Two ancillary ligands were designed in the aspect of complete energy transfer to Eu(III) ion in the complex. Both the ligands were successfully synthesized and utilized for europium complexation (Eu(TTA)3-phen-fl-mCF3,...

“…6 This allows efficient harvesting of the absorbed energy by the organic ligand(s) through the well-known antenna effect. 7 Besides, the intrinsic monochromatic red emission due to the electric-dipole (ED) 5 D 0 → 7 F 2 transition of Eu(III) 8 between 608 nm and 620 nm makes these complexes potential candidates as the red component 9 to fabricate tricolour RGB-based white organic light emitting diodes (white-OLEDs) given that the OEuCs exhibit efficient PL properties.…”

“…2 One of the promising classes of complexes for further development is the class of efficient organo-europium complexes (OEuCs) because of their exemplary photophysical properties leading to many fascinating applications such as sensors 3 and thermometers, 4 and in anti-counterfeiting applications. 5 To develop efficient OEuCs, the organic ligand(s) acting either as the primary antenna or as the ancillary ligands must have strong light absorption capabilities between 250 and 450 nm with a compatible triplet state ( 3 ππ*) leading to sufficiently separated 3 ππ* and Eu( iii ) emitting levels. 6 This allows efficient harvesting of the absorbed energy by the organic ligand(s) through the well-known antenna effect.…”

Single component white-OLEDs derived from tris(β-diketonato) europium(iii) complexes bearing the large bite angle N^N 2-(4-thiazolyl)benzimidazole ligand

“…6 This allows efficient harvesting of the absorbed energy by the organic ligand(s) through the well-known antenna effect. 7 Besides, the intrinsic monochromatic red emission due to the electric-dipole (ED) 5 D 0 → 7 F 2 transition of Eu(III) 8 between 608 nm and 620 nm makes these complexes potential candidates as the red component 9 to fabricate tricolour RGB-based white organic light emitting diodes (white-OLEDs) given that the OEuCs exhibit efficient PL properties.…”

“…2 One of the promising classes of complexes for further development is the class of efficient organo-europium complexes (OEuCs) because of their exemplary photophysical properties leading to many fascinating applications such as sensors 3 and thermometers, 4 and in anti-counterfeiting applications. 5 To develop efficient OEuCs, the organic ligand(s) acting either as the primary antenna or as the ancillary ligands must have strong light absorption capabilities between 250 and 450 nm with a compatible triplet state ( 3 ππ*) leading to sufficiently separated 3 ππ* and Eu( iii ) emitting levels. 6 This allows efficient harvesting of the absorbed energy by the organic ligand(s) through the well-known antenna effect.…”

Single component white-OLEDs derived from tris(β-diketonato) europium(iii) complexes bearing the large bite angle N^N 2-(4-thiazolyl)benzimidazole ligand

“…The CRI is calculated to be more than that for previously reported Eu complexes (tri component hybrid white LED systems). 28 Herein, from the recently synthesized mCF 3 based Eu complexes, the dual (yellow and red) emission behavior was registered in solid and solution PL spectra, and it was found to be a reliable source to generate white light from a single molecule. The prerequisite requirement is the color balancing of three primary colors.…”

New isomeric ancillary ligands and their Eu^III complexes: a single component white light emissive phosphor and their applications in red/white smart LEDs, electronic noses, and temperature sensing

“…This is a theoretical calculation carried out using the emission spectral data of the Eu(III) complexes, by the help of the equations given in the ESI. ‡ 22,[39][40][41] The J-O parameter is a straightforward constraint for analyzing the optical properties of the Eu(III) ions. 42 The detailed analyses of the J-O parameters and equations are described in the ESI ‡ (J-O section).…”

Thiabendazole: a new class of antenna core structure for multifunctional trivalent organo-europium (Eu^III) complexes