Login / Signup

Sensitization of Nd 3+ Luminescence by Simultaneous Two-Photon Excitation through a Coordinating Polymethinic Antenna.

Jesús Durán-HernándezLeonardo Muñoz-RugelesÓscar Guzmán-MéndezMariana M RezaAndrea Cadena-CaicedoVerónica García-MontalvoJorge Peón
Published in: The journal of physical chemistry. A (2022)
We have designed and synthesized two new cyaninic Nd 3+ complexes where the lanthanide emission can be induced from simultaneous two-photon absorption followed by energy migration. These complexes correspond to a molecular design that uses an antenna ligand formed by the functionalization of a heptamethine dye with 5-ol-phenanthroline or 4-phenyl-terpyridine derivatives. These complexes employ the important nonlinear optical properties of symmetric polymethines to sensitize the lanthanide ion. We verified that simultaneous biphotonic excitation indirectly induces the 4 F 3/2 → 4 I 11/2 Nd 3+ emission using femtosecond laser pulses tuned below the first electronic transition of the antenna. The simultaneous two-photon excitation events initially form the nonlinear-active second excited singlet of the polymethine antenna, which rapidly evolves into its first excited singlet. This state in turn induces the formation of the emissive Nd 3+ states through energy transfer. The role of the first excited singlet of the antenna as the donor state in this process was verified through time resolution of the antenna's fluorescence. These measurements also provided the rates for antenna-lanthanide energy transfer, which indicate that the phenanthroline-type ligand is approximately five times more efficient for energy transfer than the phenyl-terpyridine derivative due to their relative donor-acceptor distances. The simultaneous two-photon excitation of this polymethine antenna allows for high spatial localization of the Nd 3+ excitation events.
Keyphrases
  • energy transfer
  • quantum dots
  • living cells
  • single molecule
  • sensitive detection
  • oxidative stress
  • drug induced
  • diabetic rats
  • oxide nanoparticles