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Effects of Composites due to External Fields
Published:
26 May 2014
by MDPI
in 1st International Electronic Conference on Materials
session Polymers (collected papers from the ECP)
Abstract: The Properties of polymer differs when subjected to various external fields such as pH, temperature and light. As the external fields react with the polymer it results in deformation. In the present world construction industry plays a major role in using of composite materials. The composites such as FRP and polymer concrete deforms due to various external fields of nature. The focus on the present paper is the effects happen in composite materials due to external fields. Here in this paper the composite materials FRP and polymer concrete is subjected to external field and its effect is found with a case study.
Keywords: Composite materials, effects, pH, temperature and light.
Comments on this paper
Akin C
26 May 2014
Nano Changes in Polymers
Research should be focused on the question,
" At which stage the polymer effect occur?"
1. Nano level change
2. Effects occur at normal atmosphere condition
" At which stage the polymer effect occur?"
1. Nano level change
2. Effects occur at normal atmosphere condition
Akin C
28 May 2014
BIODEGRADABLE PLASTIC MADE FROM WASTE METHANE
Dear Scientific Community,
The National Science Foundation (NSF) published a new Scientific discovery on May 27,2014 stating that " The biodegradable plastic made from waste methane". This article was prepared by NSF for the American Institute of Chemical Engineers and appeared in the February 2014 issue of Chemical Engineering Progress.
Scientists are making PHA (a biodegradable polymer similar to the polypropylene used in yogurt containers) from waste methane
Scientists have developed a process to produce PHA via methane-eating bacteria.
May 27, 2014
What if we could make the Great Pacific Garbage Patch just disappear? What if plastics didn't accumulate in our landfills? What if we could reduce greenhouse gas emissions while replacing up to 30 percent of the world's plastics with a biodegradable substitute?
Researchers have tried for decades to achieve these goals. One approach being taken is the development of an efficient production process for poly-hydroxyalkanoate (PHA)a biodegradable polymer similar to the polypropylene used to make yogurt containers. Scientists at Stanford University and a Palo Alto, Calif.-based start-up company called Mango Materials have come up with a new way to make PHA from waste methane gas. And, with funding from the National Science Foundation (NSF), Mango Materials is advancing the process toward commercialization.
PHA is a biodegradable polyester that is produced naturally inside some bacteria under conditions of excess carbon and limited nutrient availability. Processes being developed to make PHA at a commercial scale typically involve bacteria strains that have been genetically modified to boost production and corn-based sugar as the carbon source.
The microorganisms feed on plant-derived sugars and produce PHA. The PHA is then separated from the bacteria and made into pellets that can be molded into plastic products. This approach has several shortcomings: It requires use of agricultural land and other inputs to produce feedstock, and it competes with the food supply.
Mango Materials' process uses bacteria grown in fermenters to transform methane and oxygen, along with added nutrients (to supply excess carbon), into PHA. Eventually, the PHA-rich bacterianow literally swollen with PHA granulesare removed from the fermenters, and the valuable polymer is separated via proprietary techniques from the rest of the cell mass. The PHA is then rinsed, cleaned, and dried as needed.
After the products made of the PHA have reached the end of their useful life, the plastic can be degraded anaerobically (without air)to produce methane gas. This closes the loop and provides a fresh feedstock for PHA production. Because PHA's properties can be tweaked by varying the copolymer content or with additives, Mango Materials has identified a range of applications. "We are currently focused on applications where biodegradability is key," says Molly Morse, CEO at Mango Materials. "However, we're open to all sorts of applications and are eager to bring PHA bioplastics to market."
This unique approach addresses challenges that have derailed previous attempts at PHA commercialization. Other processes use sugar as a carbon feedstock, whereas Mango Materials uses waste methanewhich is considerably less expensive than sugar.
"By using methane gas as the feedstock, we can significantly drive down costs of production," Morse says.
In addition, the process relies on a mixed community of wild bacteria that are obtained through natural selection rather than genetic engineering. Using wild bacteria that are not genetically altered alleviates concerns of some toward genetically modified organisms. And, the use of a mixed community of wild bacteria reduces production costs because it eliminates the need to sterilize equipment.
"This stands in contrast to the processes many biotech companies use that require high-purity, genetically engineered cultures," says Allison Pieja, director of technology at Mango Materials.
As an added environmental benefit, the process sequesters methane, a potent greenhouse gas, and provides an economic incentive for methane capture at facilities such as landfills, wastewater treatment plants and dairy farms. The unused, vented methane from California landfills (based on 2010 data from the Methane to Markets partnershipif used as PHA feedstockwould yield more than 100 million pounds per year of plastic. (This estimate is based on Mango Materials' internal calculations using its own rates and yields). Mango Materials has vetted this technology and achieved excellent yields at the lab scale. Field studies have shown that the methane-consuming cultures grow just as well on waste biogas, which includes contaminants such as sulfides, as on pure methane. Now, the company is setting out to achieve the same yields at a commercial scale. Mango Materials standard commercial plants will be sized to handle the methane produced at an average wastewater treatment plantenough to produce more than 2 million pounds per year of PHA. This technology was funded through the NSF Small Business Innovation Research Program.
Investigators Molly Morse
Related Institutions/Organizations Mango Materials
The National Science Foundation (NSF) published a new Scientific discovery on May 27,2014 stating that " The biodegradable plastic made from waste methane". This article was prepared by NSF for the American Institute of Chemical Engineers and appeared in the February 2014 issue of Chemical Engineering Progress.
Scientists are making PHA (a biodegradable polymer similar to the polypropylene used in yogurt containers) from waste methane
Scientists have developed a process to produce PHA via methane-eating bacteria.
May 27, 2014
What if we could make the Great Pacific Garbage Patch just disappear? What if plastics didn't accumulate in our landfills? What if we could reduce greenhouse gas emissions while replacing up to 30 percent of the world's plastics with a biodegradable substitute?
Researchers have tried for decades to achieve these goals. One approach being taken is the development of an efficient production process for poly-hydroxyalkanoate (PHA)a biodegradable polymer similar to the polypropylene used to make yogurt containers. Scientists at Stanford University and a Palo Alto, Calif.-based start-up company called Mango Materials have come up with a new way to make PHA from waste methane gas. And, with funding from the National Science Foundation (NSF), Mango Materials is advancing the process toward commercialization.
PHA is a biodegradable polyester that is produced naturally inside some bacteria under conditions of excess carbon and limited nutrient availability. Processes being developed to make PHA at a commercial scale typically involve bacteria strains that have been genetically modified to boost production and corn-based sugar as the carbon source.
The microorganisms feed on plant-derived sugars and produce PHA. The PHA is then separated from the bacteria and made into pellets that can be molded into plastic products. This approach has several shortcomings: It requires use of agricultural land and other inputs to produce feedstock, and it competes with the food supply.
Mango Materials' process uses bacteria grown in fermenters to transform methane and oxygen, along with added nutrients (to supply excess carbon), into PHA. Eventually, the PHA-rich bacterianow literally swollen with PHA granulesare removed from the fermenters, and the valuable polymer is separated via proprietary techniques from the rest of the cell mass. The PHA is then rinsed, cleaned, and dried as needed.
After the products made of the PHA have reached the end of their useful life, the plastic can be degraded anaerobically (without air)to produce methane gas. This closes the loop and provides a fresh feedstock for PHA production. Because PHA's properties can be tweaked by varying the copolymer content or with additives, Mango Materials has identified a range of applications. "We are currently focused on applications where biodegradability is key," says Molly Morse, CEO at Mango Materials. "However, we're open to all sorts of applications and are eager to bring PHA bioplastics to market."
This unique approach addresses challenges that have derailed previous attempts at PHA commercialization. Other processes use sugar as a carbon feedstock, whereas Mango Materials uses waste methanewhich is considerably less expensive than sugar.
"By using methane gas as the feedstock, we can significantly drive down costs of production," Morse says.
In addition, the process relies on a mixed community of wild bacteria that are obtained through natural selection rather than genetic engineering. Using wild bacteria that are not genetically altered alleviates concerns of some toward genetically modified organisms. And, the use of a mixed community of wild bacteria reduces production costs because it eliminates the need to sterilize equipment.
"This stands in contrast to the processes many biotech companies use that require high-purity, genetically engineered cultures," says Allison Pieja, director of technology at Mango Materials.
As an added environmental benefit, the process sequesters methane, a potent greenhouse gas, and provides an economic incentive for methane capture at facilities such as landfills, wastewater treatment plants and dairy farms. The unused, vented methane from California landfills (based on 2010 data from the Methane to Markets partnershipif used as PHA feedstockwould yield more than 100 million pounds per year of plastic. (This estimate is based on Mango Materials' internal calculations using its own rates and yields). Mango Materials has vetted this technology and achieved excellent yields at the lab scale. Field studies have shown that the methane-consuming cultures grow just as well on waste biogas, which includes contaminants such as sulfides, as on pure methane. Now, the company is setting out to achieve the same yields at a commercial scale. Mango Materials standard commercial plants will be sized to handle the methane produced at an average wastewater treatment plantenough to produce more than 2 million pounds per year of PHA. This technology was funded through the NSF Small Business Innovation Research Program.
Investigators Molly Morse
Related Institutions/Organizations Mango Materials
Akin C
6 June 2014
Smart material
POLYMORPH,
Polymorph is a smart material which changes its shape when it is exposed to high temperature and it comes to its original shape while coolong.
Therefore the effect on this type of polymer (polymorph) acts smart due to temparature.
Polymorph is a smart material which changes its shape when it is exposed to high temperature and it comes to its original shape while coolong.
Therefore the effect on this type of polymer (polymorph) acts smart due to temparature.
