posted on 2022-08-08, 05:20authored byJiwon Park, Seon-Mi Jin, Avnish Kumar Mishra, Jung Ah Lim, Eunji Lee
Oriental lacquer sap is attracting considerable attention
as a
renewable and eco-friendly natural resin with high durability, heat
resistance, insulation, insect repellency, and antiseptic and antibacterial
properties. However, to ensure excellent coating performance, it is
necessary to improve the drying/curing process of lacquer sap with
a time-consuming drying time at high humidity [relative humidity (RH),
70–90%] and ambient temperature (20–30 °C). Drawing
on an understanding of the polymerization mechanism of urushiol, the
main component of the lacquer sap consisted of a water-in-oil (W/O)
emulsion, and this study presents an eco-friendly additive that mimics
the structure–function of urushiol composed of a polar catechol
head group and a nonpolar hydrocarbon tail. A photo-curable lacquer
sap was thus developed by adding a tyrosine amino acid-based lipid
agent (denoted as Y-ADDA), which allows faster and more effective
drying/curing at lower humidity while maintaining the nature-derived
properties of lacquer sap. Y-ADDA easily coassembles with urushiol
in the W/O emulsion droplets, thereby significantly accelerating the
formation of a polymer network along with urushiol during water evaporation
leading to fast drying/curing under ultraviolet (UV) light irradiation
at low humidity (∼50% RH). The UV-cured lacquer sap resins
showed higher performance in terms of film processing and physicochemical
properties compared with that of the lacquer containing only tyrosine
amino acids without aliphatic tail conjugation, N-(9-fluorenylmethoxycarbonyl)-O-tert-butyl-l-tyrosine Fmoc-Tyr(tBu)-OH. Furthermore,
the drying and curing times, film morphology, transmittance, hardness,
and adhesion strength of the UV-cured lacquer were markedly superior
compared to those of shellac, a general eco-friendly fast-drying primer.
The study provides useful strategies and insights to promote the industrial
application of lacquer sap resins by employing biocompatible nanoagents
developed with an understanding of the curing mechanism of natural
resins and from the viewpoint of green and sustainable chemistry perspective.