Abstract
Examples of molecular complexes acting as thermometers operating at room temperature in near infrared region are scarce, therefore this work showcases the anti-thermal quenching effect on neodymium(III) molecular thermometers working in biological windows within the physiological temperature range. A mononuclear complex, [Nd(L)(NO(3))(3)] (1Nd), where L is a macrocyclic ligand, was synthesized and used as a precursor to develop two novel species: a dinuclear, [(Nd(L)(NO(3)))(2)(µ-BDC)](NO(3))(2)·H(2)O (2Nd), linked by 1,4-benzenedicarboxylate (BDC), and a hexameric, [(Nd(L))(µ-BTC)(H(2)O)](6)·35H(2)O (6Nd), linked with 1,3,5-benzenetricarboxylate (BTC). Thermometric properties were studied in the physiological temperature range (292-332 K), utilizing 804 nm laser excitation (first biological window) and monitoring emissions in the second biological window (908, 1065, and 1340 nm) associated with the (4)F(3/2) → (4)I(9/2), (4)I(11/2), (4)I(13/2) transitions, respectively. Among the complexes, the hexamer 6Nd exhibited exceptional performance, with S(r) of 2.4%K(-1) at 293 K, when luminescence intensity ratio (LIR) of two Stark components of the (4)F(3/2) → (4)I(11/2) emission was used, positioning it as a high-performance Nd(III)-based thermometer. All complexes displayed anti-thermal quenching behavior, surpassing the current molecular-based thermometers in the near-infrared region. Theoretical calculations using complete active space self consistent field (CASSCF) and Boltzmann population models between Kramers doublets of the (4)F(3/2) level were performed to rationalize the anti-thermal behavior.