What does this research mean for the field?

Dual-parameter molecular engineering of dibenzylidene ketone photoinitiators enhances their performance in one-photon polymerization and two-photon lithography, achieving high-resolution microfabrication. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

The research aims to enhance the properties of dibenzylidene ketone photoinitiators for one-photon and two-photon polymerization using molecular engineering.

March 13, 2026

Alkyl/Cycloketonic Modulations in Photoinitiator Molecular Engineering for Efficient Multiphoton Polymerization †

Key Points

The research aims to enhance the properties of dibenzylidene ketone photoinitiators for one-photon and two-photon polymerization using molecular engineering.
Developed dual-parameter molecular engineering for tert‐butylcarbazole-functionalized DBK PIs.
Tuned N-alkyl chains (methyl to n-dodecyl) and cyclic ketone spacers (C5, C6).
Evaluated polymerization properties under LED and fs laser.
Assessed photosensitivity, solubility, and polymerization efficiency.
C5-DBK photoinitiators showed improved visible photosensitivity and rapid polymerization kinetics.
N-dodecyl derivatives exhibited excellent photobleaching and deep curing properties.
C5-DBKs had superior two-photon absorption compared to C6-DBKs, which had better solubility.
Achieved sub-200 nm resolution in high-precision fabrications using PETA and a fs laser.

Abstract

Comprehensive Summary Dibenzylidene ketone (DBK) photoinitiators (PIs) hold promise for one‐photon polymerization (OPP) and two‐photon lithography (TPL), owing to easily synthesized extended π‐conjugated frameworks via one‐step aldol condensation. However, industrial adoption is limited by poor solubility and critical OPP reactivity/TPL processability mismatch. Herein, we report a dual‐parameter molecular engineering strategy for tert ‐butylcarbazole‐functionalized DBK PIs, tuning N ‐alkyl chains (methyl, ethyl, n ‐butyl, n ‐dodecyl) and cyclic ketone spacers (C5: cyclopentanone; C6: cyclohexanone) to optimize polymerization properties. For OPP, C5‐DBKs exhibit enhanced visible photosensitivity, enabling rapid kinetics under 405–520 nm LEDs; N ‐dodecyl derivatives show excellent photobleaching and deep curing. For TPL, C5‐DBKs have superior two‐photon absorption ( σ TPA ) but C6‐DBKs offer better solubility (1 wt% in PETA) and act as efficient one‐component TPL PIs. Using a 780 nm fs laser, N1C6/PETA enables high‐precision fabrication: threshold matrix writing exhibits wide processing window and good uniformity, achieving sub‐200 nm resolution (167 nm linewidth at 45 mW, 50 mm·s –1 ) and high‐fidelity microlens arrays. Complex 3D microstructures (intricate logos, sub‐micron text, Chinese jade belt bridge, nanoscale‐pore photonic crystals) demonstrate versatility in photonics, metamaterials and micro‐pattern anti‐counterfeiting. This work establishes OPP/TPL structure‐activity relationships (SARs) and a versatile molecular design platform for industrial coatings and micro/nano‐manufacturing.

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