Speedy sterilization: A Stanford researcher pours water through a funnel fitted with a cotton-nanotube filter that rapidly kills bacteria. The red cords supply electricity to the device, which uses electrical fields to poke holes in the bacteria.
Technology Review
Cotton fabric treated with nano inks produces a water filter that's efficient and needs little power to work.
A water filter under development at Stanford University removes bacteria from water quickly and without clogging--and could lead to a simple and inexpensive method of cleaning water for the developing world. The device, which uses a piece of cotton treated with nanomaterial inks, kills bacteria with electrical fields but uses just 20 percent of the power required by pressure-driven filters.
At least a billion people have access only to water contaminated by pathogens or pollution. "There is a huge need for an extremely robust, low-cost filter material that does not require a lot of power," says Mark Shannon, who directs a center of advanced materials for water purification at the University of Illinois at Urbana-Champaign. "Most places that need this the most do not have electricity at all, or at most a couple of hours a day," says Shannon, who is not involved with the research.
The filter developed by the Stanford researchers tries to improve on other "point-of-use" systems for removing bacteria outside of centralized water treatment facilities. There are two major chemical methods: adding chlorine to the water to kill the bacteria, or adding iron, which causes the bacteria to clump so it's easily removed. Chemical methods are difficult because they require training and a continual supply of the chemicals.
Filtration, in contrast, is attractive because it's simple. But most point-of-use filtration methods move bacteria from water by excluding the organisms by size. Such filters clog over time, and they work very slowly unless energy-intensive pumping pushes the water through. The Stanford filter, which is driven by gravity, has pores large enough to allow for a high flow rate--about 100,000 liters per hour. It uses electrical pulses to inactivate bacteria by poking holes in their cell walls. The research was led by Stanford materials science and engineering professors Yi Cui and Sarah Heilshorn.
To make the filter, researchers dip a piece of cotton batting in a water-based carbon-nanotube ink, let it dry, then dip it in an alcohol-based silver-nanowire ink and let it dry again. Cui and others have used similar dipping methods to make paper-nanotube battery electrodes and nanotube textiles. The long, narrow nanotubes and nanowires get enmeshed in the fibers.
So far, the researchers have been testing the filters by stuffing them into a glass funnel mounted over a beaker. The filter is connected to electrical wiring to provide a voltage as water is poured through the funnel. Cui says it could be powered with car batteries or solar panels.
Cui's group has tested the filter against high concentrations of E. coli. In these preliminary tests, described online in the journal Nano Letters, the filter inactivated about 98 percent of the bacteria. Even a single bacterium can make you sick, so that's not good enough for use in the field, but Cui hopes to improve the filters.
Saudi Arabia's newest purification plant will use state-of-the-art solar technology.
A dip in nanotube ink turns ordinary office paper into a high-energy electrode.
Textiles coated with carbon nanotubes form electronic sensors that look and feel like ordinary cotton.
Well meaning, but delusional...
Producing potable water on a mass scale was more or less solved 100 years ago.
It doesn't take much of a technology: filter away big residues, and then kill most microorganisms with chlorine. In newer developments, microorganisms can be killed with UV and X-rays, instead of chlorine. Since the "1st world" used chlorine for many, many decades, probably the "developing world" will be ok using it for a while too. Unless they turn up their noses...
The water filters are usually lower than low-tech: we are talking about filters made of sand and gravel. Chlorine is cheap too, and you do not need much at all.
And finally, do you think people in the "developing world" who cannot even filter water through sand and gravel, will have running electricity and "carbon-nanotube ink" for these filters? You guys are delusional!
Re: Well meaning, but delusional...
Another model the third world could emulate is pluralistic democracy with term limits.
The Wilderness Medical Society meetings I have attended usually stress that the safest and simplest method (and cheapest) is filtration through clothing material,then boiling over a fire.212degreesF. will kill all bacteria and viruses.
Can these nano cloths be installed on a deep sea pipe of some sort, then electified in the same manner deep sea fiber optic repeaters are, so they're able to separate sodium from fresh water. The pressure from the ocean itself can drive the clean water to the surface where it can be pumped where it's needed.
The research in this report is very interesting and could be a breakthrough in affordable clean water technology. We should keep in mind, however, that the concept of chemically active filters (as opposed to size exclusion filtration) is not unique to this work. The mention of nano sized silver raises some questions. First, did the researchers do control runs with no electric field applied, in order to differentiate between the inherent antibacterial effect of silver and the (electrochemical?) mechanism at work in their filter. Second, silver is costly. Did the researchers report how much silver was used to construct a filter having a specified water throughput?
ceramic water purifier (colloidal silver)
low tech + cottage industry
http://s189535770.onlinehome.us/pottersforpeace/?page_id=9
Well if the 3rd world can't use it, he can always market it to the world Aquarium market.
They are keen to find a way to kill bacteria in water without using all the dangerous drugs or dyes they use currently which harms fish.
I am wondering if it would kill spores? Since bacterial spores do not have a cell wall I doubt that bacterial spores would be affected at all. In all I have to agree that this is nothing more than an interesting thesis project getting to much attention.
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Gaetano Marano
246 Comments
>>> the Watercone >>>
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very good and very "high-tech" but the fastest and simplest way to produce small amounts of clean water at low costs still is the WATERCONE:
http://offtopicnews.blogspot.com/2009/02/un-geniale-dissalatore-low-tech-da-30.html
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mkogrady
423 Comments
Re: >>> the Watercone >>>
Didn't Survivorman build an inverse version of a water cone using sand and plastic, then distill his urine with it?
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