30 research outputs found
Synthesis and Properties of a Photopolymerizable Carbene-Mediated Poly Phosphinate Flame Retardant by Carbene Polymerization
A novel photopolymerizable poly phosphinate
(poly ethyl (4-acrylamidebenzyl)Âphosphinate,
P-NH-AC) flame retardant was synthesized by a carbene polymerization
and characterized using Fourier transform infrared spectroscopy (FTIR),
nuclear magnetic resonance spectroscopy (NMR), and gel permeation
chromatography (GPC). The effect of P-NH-AC on the kinetics of photopolymerization,
thermal stability, combustion behaviors, and physical and mechanical
properties of the UV-cured materials were investigated by real-time
infrared spectroscopy (RT-IR), thermogravimetric analysis (TGA), thermogravimetric
analysis/infrared spectrometry (TGA-IR), the limiting oxygen index
(LOI), and the cone calorimetric test (CCT). For the systems with
P-NH-AC, the thermal stability was improved with the increase of the
P-NH-AC; however, the final residue of all systems was low. The addition
of 5% P-NH-AC increased the LOI from 29.0 to 32.0. The addition of
P-NH-AC significantly decreased the heat release rate (HRR), total
heat release (THR), and total smoke production (TSP) of the resin.
Moreover, P-NH-AC can also improve physical and mechanical properties
of the materials
Photocured Materials with Self-Healing Function through Ionic Interactions for Flexible Electronics
Photocured
materials with self-healing function have the merit
of long lifetime and environmentally benign preparation process and
thus find potential applications in various fields. Herein, a novel
imidazolium-containing photocurable monomer, (6-(3-(3Â(2-hydroxyethyl)-1<i>H</i>-imidazol-3-ium bromide)Âpropanoyloxy)Âhexyl acrylate, IM-A),
was designed and synthesized. Self-healing polymers were prepared
by fast photocuring with IM-A, isobornyl acrylate, 2-(2-ethoxyethoxy)Âethyl
acrylate, and 2-hydroxyethyl acrylate as the monomers. The mechanical
and self-healing properties of the polymers were tuned by varying
the contents of IM-A and other monomers. The as-prepared self-healing
polymer IB7-IM5 exhibited a tensile strength of 3.1 MPa, elongation
at break of 205%, healing efficiency of 93%, and a wide healing temperature
range from room temperature to 120 °C. The self-healing polymer
was also employed as a flexible substrate to fabricate a flexible
electronic device, which could be healed and completely restore its
conductivity after the device was damaged
Compositional Gradients in Siloxane Copolymers by Photocontrolled Surface Segregation
We demonstrate how to tune the surface
chemistry and properties
of copolymers obtained by the photopolymerization of polyoxyethylene
(meth)Âacrylic monomers and a low polarity siloxane comonomer which
spontaneously migrates to the free surface. By controlling the photopolymerization
conditions, such as the light gradient through the thickness of the
film and selecting the proper monomer functionality, it is possible
to optimize and photoenforce the surface segregation of the siloxane
comonomer. Photocured films containing the same amount of siloxane
component (1 wt %) can exhibit a surface energy ranging from 42 to
22 mN m<sup>–1</sup> depending on the process conditions. XPS
and AFM analyses confirm that polymers with a compositional gradient
are obtained and that the surface segregation can be finely photocontrolled.
Photopolymerization is thus proven to be a facile, single step method
for generating gradient films and for independently and simultaneously
tune their surface and bulk properties
Synthesis and Characterization of Alkali-Soluble Hyperbranched Photosensitive Polysiloxane Urethane Acrylate
A novel alkali-soluble hyperbranched photosensitive polysiloxane urethane acrylate (AHBPSUA) was synthesized by using hyperbranched polyesters, hydroxyl-terminated polysiloxane, dimethylolpropionic acid, isophorone diisocyanate, and 2-hydroxyethyl acrylate as raw materials, and its structure was characterized by Fourier transform infrared spectroscopy, gel permeation chromatography, and <sup>1</sup>H nuclear magnetic resonance spectroscopy. It was found that AHBPSUA possessed good compatibility with a number of acrylate monomers. The effect of photoinitiators and monomers on the photopolymerization kinetics of AHBPSUA was investigated by real-time infrared spectroscopy (RT-IR). The results showed that AHBPSUA could rapidly photopolymerize under UV irradiation in the presence of a photoinitiator and the optimal concentration of the photoinitiator (Darocur 1173) was determined as 0.1 wt %. The resin of AHBPSUA with common acrylic monomers exhibited a high polymerization rate and double-bond conversion and could form a regular image under UV irradiation through a patterned mask. The AHBPSUA system could dissolve in 1 wt % sodium carbonate solution easily and completely, and the cured coating film of the AHBPSUA system possessed excellent flexibility, toughness, and heat resistance
Photocured Materials with Self-Healing Function through Ionic Interactions for Flexible Electronics
Photocured
materials with self-healing function have the merit
of long lifetime and environmentally benign preparation process and
thus find potential applications in various fields. Herein, a novel
imidazolium-containing photocurable monomer, (6-(3-(3Â(2-hydroxyethyl)-1<i>H</i>-imidazol-3-ium bromide)Âpropanoyloxy)Âhexyl acrylate, IM-A),
was designed and synthesized. Self-healing polymers were prepared
by fast photocuring with IM-A, isobornyl acrylate, 2-(2-ethoxyethoxy)Âethyl
acrylate, and 2-hydroxyethyl acrylate as the monomers. The mechanical
and self-healing properties of the polymers were tuned by varying
the contents of IM-A and other monomers. The as-prepared self-healing
polymer IB7-IM5 exhibited a tensile strength of 3.1 MPa, elongation
at break of 205%, healing efficiency of 93%, and a wide healing temperature
range from room temperature to 120 °C. The self-healing polymer
was also employed as a flexible substrate to fabricate a flexible
electronic device, which could be healed and completely restore its
conductivity after the device was damaged
Photocured Materials with Self-Healing Function through Ionic Interactions for Flexible Electronics
Photocured
materials with self-healing function have the merit
of long lifetime and environmentally benign preparation process and
thus find potential applications in various fields. Herein, a novel
imidazolium-containing photocurable monomer, (6-(3-(3Â(2-hydroxyethyl)-1<i>H</i>-imidazol-3-ium bromide)Âpropanoyloxy)Âhexyl acrylate, IM-A),
was designed and synthesized. Self-healing polymers were prepared
by fast photocuring with IM-A, isobornyl acrylate, 2-(2-ethoxyethoxy)Âethyl
acrylate, and 2-hydroxyethyl acrylate as the monomers. The mechanical
and self-healing properties of the polymers were tuned by varying
the contents of IM-A and other monomers. The as-prepared self-healing
polymer IB7-IM5 exhibited a tensile strength of 3.1 MPa, elongation
at break of 205%, healing efficiency of 93%, and a wide healing temperature
range from room temperature to 120 °C. The self-healing polymer
was also employed as a flexible substrate to fabricate a flexible
electronic device, which could be healed and completely restore its
conductivity after the device was damaged
Synthesis and characterization of photosensitive-fluorosilicone–urethane acrylate prepolymers
<div><p>Two kinds of novel photosensitive-fluorosilicone–urethane acrylate prepolymers (Si-F15-IPDI-HEA/Si-F6-IPDI-HEA) were synthesized and characterized. Si-F15-IPDI-HEA and Si-F6-IPDI-HEA were able to form homogeneous mixtures with a number of acrylate monomers. Formulations with these prepolymers with common acrylic monomers exhibited high-polymerization rates and final double-bond conversion over 90% after irradiation for 60 s. It was found the final conversion decreased with the increase of the functionality of the monomer. The influence of the monomer and prepolymers on the properties of the UV-cured films was systematically studied. Thermostability property along with mechanical performance was improved with the increase of the functionality of monomers and prepolymers. A decrease of water absorption was also observed through water contact angle measurements. The UV-cured films of Si-F15-IPDI-HEA and Si-F6-IPDI-HEA possessed an excellent adhesion on the PU and PVC leather, providing a potential application in leather industry as a finishing and coating agent.</p></div
Synthesis and Properties of Photosensitive Silicone-Containing Polyurethane Acrylate for Leather Finishing Agent
A photosensitive silicone-containing
polyurethane acrylate prepolymer
(Si-IPDI-HEA) was synthesized and characterized adequately by FTIR, <sup>1</sup>H NMR, and GPC analyses. The effect of the monomers on the
photopolymerization kinetics of Si-IPDI-HEA was investigated by real-time
infrared spectroscopy (RT-IR). The results showed that the resin of
Si-IPDI-HEA with common acrylic monomers exhibited a high polymerization
rate and double-bond conversion. The influence of the monomer and
silicone on the microstructure and properties of the UV-cured film
also was systematically studied. It was found that, with the increase
of the functionality of the monomer, the thermostability, <i>T</i><sub>g</sub>, hardness, tensile strength, tensile modulus,
and dispersion surface energy of the UV-cured film were increased,
whereas the contact angle and elongation at break were decreased.
The introduction of silicone into the prepolymer could enhance the
thermostability of the UV-cured film, and reduce the dispersion surface
energy by the change of the microstructure. More importantly, the
leather finishing agent containing Si-IPDI-HEA has excellent comprehensive
performance and potential application in the leather finishing agent
Both Complexity and Location of DNA Damage Contribute to Cellular Senescence Induced by Ionizing Radiation
<div><p>Persistent DNA damage is considered as a main cause of cellular senescence induced by ionizing radiation. However, the molecular bases of the DNA damage and their contribution to cellular senescence are not completely clear. In this study, we found that both heavy ions and X-rays induced senescence in human uveal melanoma 92–1 cells. By measuring senescence associated-β-galactosidase and cell proliferation, we identified that heavy ions were more effective at inducing senescence than X-rays. We observed less efficient repair when DNA damage was induced by heavy ions compared with X-rays and most of the irreparable damage was complex of single strand breaks and double strand breaks, while DNA damage induced by X-rays was mostly repaired in 24 hours and the remained damage was preferentially associated with telomeric DNA. Our results suggest that DNA damage induced by heavy ion is often complex and difficult to repair, thus presents as persistent DNA damage and pushes the cell into senescence. In contrast, persistent DNA damage induced by X-rays is preferentially associated with telomeric DNA and the telomere-favored persistent DNA damage contributes to X-rays induced cellular senescence. These findings provide new insight into the understanding of high relative biological effectiveness of heavy ions relevant to cancer therapy and space radiation research.</p></div
Synthetic Strategy and Performances of a UV-Curable Poly Acryloyl Phosphinate Flame Retardant by Carbene Polymerization
<div><p>GRAPHICAL ABSTRACT</p><p></p></div