Tunable Energy-Transfer Process in Heterometallic MOF Materials Based on 2,6-Naphthalenedicarboxylate: Solid-State Lighting and Near-Infrared Luminescence Thermometry
authors Gomez, GE; Marin, R; Neto, ANC; Botas, AMP; Ovens, J; Kitos, AA; Bernini, MC; Carlos, LD; Soler-Illia, GJAA; Murugesu, M
nationality International
journal CHEMISTRY OF MATERIALS
keywords METAL-ORGANIC FRAMEWORKS; BUILDING UNITS; COORDINATION-COMPOUNDS; TOPOLOGICAL ANALYSIS; CRYSTAL-STRUCTURES; EMISSION; NANOPARTICLES; POLYMERS; SERIES; NETS
abstract Trivalent lanthanide ions (Ln(3+)) are used to prepare a plethora of coordination compounds, with metal-organic frameworks (MOFs) being among the most sought-after in recent years. The porosity of Ln-MOFs is often complemented by the luminescence imparted by the metal centers, making them attractive multifunctional materials. Here, we report a class of three-dimensional (3D) MOFs obtained from a solvothermal reaction between 2,6-naphthalenedicarboxylic acid (H2NDC) and lanthanide chlorides, yielding three types of compounds depending on the chosen lanthanide: [LnCl(NDC)-(DMF)] for Ln(3+) = La3+, Ce3+, Pr3+, Nd3+, Sm3+ (type 1), [Eu(NDC)(1.5)(DMF)]center dot 0.5DMF (type 2), and [Ln(2)(NDC)(3)(DMF)(2)] for Ln(3+) = Tb3+, Dy3+, Y3+, Er3+, Yb3+ (type 3). Photoluminescent properties of selected phases were explored at room temperature. The luminescence thermometry capability of Yb3+-doped Nd-MOF was fully investigated in the 15-300 K temperature range under 365 and 808 nm excitation. To describe the optical behavior of the isolated MOFs, we introduce the total energy-transfer balance model. Therein, the sum of energy-transfer rates is considered along with its dependence on the temperature-the sign, magnitude, and variation of this parameter-permitting to afford a thorough interpretation of the observed behavior of the luminescent species of all materials presented here. The combination of novel theoretical and experimental studies presented herein to describe energy-transfer processes in luminescent materials can pave the way toward the design of MOF-based chemical and physical sensors working in an optical range of interest for biomedical applications.
publisher AMER CHEMICAL SOC
issn 0897-4756
isbn 1520-5002
year published 2020
volume 32
issue 17
beginning page 7458
ending page 7468
digital object identifier (doi) 10.1021/acs.chemmater.0c02480
web of science category Chemistry, Physical; Materials Science, Multidisciplinary
subject category Chemistry; Materials Science
unique article identifier WOS:000569075300036
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journal analysis (jcr 2019):
journal impact factor 9.567
5 year journal impact factor 10.102
category normalized journal impact factor percentile 88.386
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