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New recipe for self-healing plastic includes dash of food additive
October 16, 2008CHAMPAIGN, Ill. - Adding a food additive to damaged polymers can help restore them to full strength, say scientists at the University of Illinois who cooked up the novel, self-healing system.
The repair process, in which solvent-filled microcapsules embedded in an epoxy matrix rupture when a crack forms, is a major improvement over the original self-healing process first described in February 2001.
"While our previous solvent worked well for healing, it was also toxic," said Scott White, a professor of aerospace engineering and a researcher at the university's Beckman Institute. "Our new solvent is both non-toxic and less expensive."
During normal use, epoxy-based materials experience stresses that can cause cracking, which can lead to mechanical failure. Autonomic self-healing - a process in which the damage itself triggers the repair mechanism - can retain structural integrity and extend the lifetime of the material.
Designed to mimic the human body's ability to repair wounds, self-healing materials release a healing agent into the crack plane when damaged, and through chemical and physical processes, restore the material's initial fracture properties.
In November 2007, White and collaborators reported the use of chlorobenzene, a common - but toxic - organic solvent, which in epoxy resins achieved a healing efficiency of up to 82 percent.
In their latest work, which combined a non-toxic and Kosher-certified food additive (ethyl phenylactate) and an unreacted epoxy monomer into microcapsules as small as 150 microns in diameter, the researchers achieved a healing efficiency of 100 percent.
"Previously, the microcapsules contained only solvent, which flowed into the crack and allowed some of the unreacted matrix material to become mobile, react and repair the damage," said graduate research assistant Mary Caruso. "By including a tiny amount of unreacted epoxy monomer with the solvent in the microcapsules, we can provide additional chemical reactivity to repair the material."
When the epoxy monomer enters the crack plane, it bonds with material in the matrix to coat the crack and regain structural properties. In tests, the solvent-epoxy monomer combination was able to recover 100 percent of a material's virgin strength after damage had occurred.
"This work helps move self-healing materials from the lab and into everyday applications," said graduate research assistant Benjamin Blaiszik. "We've only begun to scratch the surface of potential applications using encapsulated solvent and epoxy resin."
University of Illinois at Urbana-Champaign
During normal use, epoxy-based materials experience stresses that can cause cracking, which can lead to mechanical failure. Autonomic self-healing - a process in which the damage itself triggers the repair mechanism - can retain structural integrity and extend the lifetime of the material.
Designed to mimic the human body's ability to repair wounds, self-healing materials release a healing agent into the crack plane when damaged, and through chemical and physical processes, restore the material's initial fracture properties.
In November 2007, White and collaborators reported the use of chlorobenzene, a common - but toxic - organic solvent, which in epoxy resins achieved a healing efficiency of up to 82 percent.
In their latest work, which combined a non-toxic and Kosher-certified food additive (ethyl phenylactate) and an unreacted epoxy monomer into microcapsules as small as 150 microns in diameter, the researchers achieved a healing efficiency of 100 percent.
"Previously, the microcapsules contained only solvent, which flowed into the crack and allowed some of the unreacted matrix material to become mobile, react and repair the damage," said graduate research assistant Mary Caruso. "By including a tiny amount of unreacted epoxy monomer with the solvent in the microcapsules, we can provide additional chemical reactivity to repair the material."
When the epoxy monomer enters the crack plane, it bonds with material in the matrix to coat the crack and regain structural properties. In tests, the solvent-epoxy monomer combination was able to recover 100 percent of a material's virgin strength after damage had occurred.
"This work helps move self-healing materials from the lab and into everyday applications," said graduate research assistant Benjamin Blaiszik. "We've only begun to scratch the surface of potential applications using encapsulated solvent and epoxy resin."
University of Illinois at Urbana-Champaign
Tiny capsules deliver
A tiny particle syringe composed of polymer layers and nanoparticles may provide drug delivery that targets diseased cells without harming the rest of the body, according to a team of chemical engineers. This delivery system could be robust and flexible enough to deliver a variety of substances.
New polymer coatings prevent corrosion, even when scratched
Imagine tiny cracks in your patio table healing by themselves, or the first small scratch on your new car disappearing by itself. This and more may be possible with self-healing coatings being developed at the University of Illinois.
Carnegie Mellon researchers to develop new drug delivery system
Carnegie Mellon University's Stefan F. Zappe is using adult neural stem cells to develop a new stem cell-based drug delivery therapy that may ultimately help treat a variety of inherited genetic disorders like Hunter syndrome.
New 'self-exploding' microcapsules could take sting out of drug delivery
Belgian chemists have developed "self-exploding" microcapsules that could one day precisely release drugs and vaccines inside the human body weeks or even months after injection.
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