Resins for Frontal Photopolymerization: Combining Depth-Cure and Tunable Mechanical Properties

Ebner, Christian; Mitterer, Julia; González-Gutiérrez, Joamín; Rieß, Gisbert; Kern, Wolfgang

doi:10.3390/ma14040743

Cited by 10 publications

(13 citation statements)

References 37 publications

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“…The current study showed that composites with an added color modifier of greater than 1 wt% exhibited DC values lower than 40%, even after being light-cured for 40 s. It is known that the maximum curing depth in light-activated free-radical polymerization is limited by the attenuation of curing light. This could be explained using Beer-Lambert's law [33,34] (Equation ( 6))…”

Section: Discussionmentioning

confidence: 99%

Effects of Color Modifier on Degree of Monomer Conversion, Biaxial Flexural Strength, Surface Microhardness, and Water Sorption/Solubility of Resin Composites

et al. 2021

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Color modifiers can be mixed with resin composites to mimic the shade of severely discolored tooth. The aim of this study was to assess the effects of a color modifier on the physical and mechanical properties of a resin composite. The composite was mixed with a color modifier at 0 wt% (group 1), 1 wt% (group 2), 2.5 wt% (group 3), or 5 wt% (group 4). The degree of monomer conversion (DC) was examined after light curing for 20 or 40 s. Biaxial flexural strength (BFS)/modulus (BFM), surface microhardness (SH), and water sorption (Wsp)/solubility (Wsl) were also tested. The DC of group 1 was significantly higher than that of groups 3 and 4. The increase in curing time from 20 to 40 s increased the DC by ~10%. The BFS, BFM, Wsp, and Wsl of all the groups were comparable. A negative correlation was detected between the concentration of color modifier and the BFS and DC, while a positive correlation was observed with Wsp. In conclusion, the color modifier reduced the DC of composites, but the conversion was improved by extending the curing time. The increase in color modifier concentration also correlated with a reduction in strength and the increase in the water sorption of the composites.

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Section: Discussionmentioning

confidence: 99%

Effects of Color Modifier on Degree of Monomer Conversion, Biaxial Flexural Strength, Surface Microhardness, and Water Sorption/Solubility of Resin Composites

et al. 2021

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“…[40,41] The cationic frontal photopolymerization, known as radical-induced cationic frontal polymerization (RICFP) technique, is very promising for curing thick epoxy samples, as already reported in the literature. [42][43][44] The mechanism involves the photo-cleavage of an iodonium salt which generates a superacid that can start the cationic ring-opening epoxy polymerization. The heat release will cleave the thermo-labile initiator generating reactive radicals, which are oxidized in the presence of iodonium salt, forming a reactive carbocation.…”

Section: Introductionmentioning

confidence: 99%

Frontal‐Photopolymerization of Fully Biobased Epoxy Composites

Noè

Hakkarainen

Malburet

et al. 2022

Macro Materials & Eng

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The radical‐induced cationic frontal photopolymerization (RICFP) of fully biobased epoxy composites is successfully demonstrated. This curing strategy considerably reduces the curing time and improves the efficiency of the composite fabrication. Two different natural fiber fabrics made of cellulose and flax fibers are embedded in two epoxy matrices, one derived from vanillin (diglycidylether of vanillyl alcohol‐DGEVA) and the other from petroleum (3,4‐epoxycyclohexylmethyl 3,4‐epoxycyclohexanecarboxylate‐CE). After RICFP the composites are characterized by means of dynamic mechanical thermal analysis and tensile tests. The mechanical properties improved with increasing fiber content, confirming a strong adhesion between the matrix and the reinforcing fiber fabrics, which is further evidenced by scanning electron microscopy analyses of the fracture surfaces. Furthermore, these fully bio‐based composites possess comparable or even higher mechanical strength compared with the corresponding epoxy composites fabricated with conventional CE resin. A promising facile route to high‐performing natural fiber‐biobased epoxy resin composites is presented.

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“…Photobleaching PIs undergo photochemical reactions under irradiation, causing the absorbance in the visible-light region to decrease or even disappear completely; this effect can not only realize the colorlessness of materials but also increases light penetration to obtain thick materials. 41,42 Therefore, the development of visible LED PIs with photobleaching properties is of great importance for photocuring. Considerable work has been done on photobleaching PIs, including type I PIs, such as tetrakis (2,4,6-trimethylbenzoyl) stannane 43 and coumarin oxime esters, 44,45 and type II PIs, such as cinna-moyl, 46 curcumin, 47 and thiacarbocyanines.…”

Section: Introductionmentioning

confidence: 99%

Fused carbazole–coumarin–ketone dyes: high performance and photobleachable photoinitiators in free radical photopolymerization for deep photocuring under visible LED light irradiation

et al. 2022

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Resins for Frontal Photopolymerization: Combining Depth-Cure and Tunable Mechanical Properties

Cited by 10 publications

References 37 publications

Effects of Color Modifier on Degree of Monomer Conversion, Biaxial Flexural Strength, Surface Microhardness, and Water Sorption/Solubility of Resin Composites

Effects of Color Modifier on Degree of Monomer Conversion, Biaxial Flexural Strength, Surface Microhardness, and Water Sorption/Solubility of Resin Composites

Frontal‐Photopolymerization of Fully Biobased Epoxy Composites

Fused carbazole–coumarin–ketone dyes: high performance and photobleachable photoinitiators in free radical photopolymerization for deep photocuring under visible LED light irradiation

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