What question did this study set out to answer?

This research aims to explore how iodide coordination and methylation affect two-photon absorption in carbazole-based probes.

April 10, 2026

Unlocking Giant Two‐Photon Absorption Through Iodine Coordination in A‐π‐D‐π‐A Carbazole‐Based Probes

Key Points

This research aims to explore how iodide coordination and methylation affect two-photon absorption in carbazole-based probes.
Utilized density functional theory (DFT) and time-dependent DFT (TD-DFT) calculations.
Investigated the effects of N-methylation on terminal pyridine groups.
Analyzed the impact of iodide ions coordination with pyridinium nitrogen on absorption efficiency.
Methylation converts pyridine to pyridinium, improving charge transfer efficiency.
Iodide ion coordination significantly increases the long-wavelength two-photon absorption cross-section.
A resonant one-step transition mechanism underlies the enhanced absorption.

Abstract

ABSTRACT The strategic modulation of two‐photon absorption (TPA) in A‐π‐D‐π‐A carbazole‐based probes, achieved through N‐methylation of terminal pyridine groups and subsequent iodide ion coordination, is unveiled by density functional theory (DFT)/TD‐DFT calculations. We demonstrate that methylation transforms pyridine into pyridinium nitrogen, markedly enhancing intramolecular charge transfer efficiency. The subsequent introduction of iodide ions uniquely coordinates with the pyridinium nitrogen, triggering a dramatic surge in the long‐wavelength TPA cross‐section. This enhancement is primarily attributed to a resonant one‐step TPA transition mechanism. Our findings establish a potent strategy for the rational design of high‐performance biological imaging probes with tailored response wavelengths.

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Unlocking Giant Two‐Photon Absorption Through Iodine Coordination in A‐π‐D‐π‐A Carbazole‐Based Probes

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Abstract

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