 |
|
Controlling the movement of water through nanotube membranes
February 14, 2007By fusing wet and dry nanotechnologies, researchers at Rensselaer Polytechnic Institute have found a way to control the flow of water through carbon nanotube membranes with an unprecedented level of precision. The research, which will be described in the March 14, 2007 issue of the journal Nano Letters, could inspire technologies designed to transform salt water into pure drinking water almost instantly, or to immediately separate a specific strand of DNA from the biological jumble.
Nanotube membranes have fascinated researchers with their combination of high flow rates and high selectivity, allowing them to filter out very small impurities and other organic materials like DNA and proteins from materials with high water content. The problem is that nanotube arrays are hydrophobic, strongly repelling water.
"We have, at a very fundamental level, discovered that there is a new mechanism to control water transport," said Nikhil Koratkar, associate professor of mechanical engineering at Rensselaer and lead author of the paper. "This is the first time that electrochemical means can be used to control the way that the water interacts with the surface of the nanotube."
A group of Rensselaer researchers led by Koratkar has found a way to use low-voltage electricity to manipulate the flow of water through nanotubes. Control of water's movement through a nanotube with this level of precision has never been demonstrated before.
"In this century one of the big challenges is how to get clean drinking water," Koratkar said. "If you can remove salt from water you can solve this problem. Nature does this all the time. The first step to getting to this process is to control the flow of water through nanochannels, which we have now successfully demonstrated. This is the starting part of the research. The next step would be to capture specific proteins, DNA, or impurities within the water with specifically designed nanotubes."
The researchers discovered that when the nanotube's membrane is given a small positive potential of only 1.7 volts, and the water is given a negative potential, the nanotubes quickly switch from repelling water to pumping water through the tube. When the charge on the water is raised, the water flows through at an exponentially faster rate. When the experiment is reversed with a negatively charged nanotube, it takes much higher voltage (90 volts) to move the water through the tube.
By simply reversing the polarity of the nanotubes, the team found that they could actually start and stop the flow of water through the tube. When a small positive charge is administered the water moves through the tube, and when that charge is reversed the water flow stops.
The researchers determined that the nanotube walls had been electrochemically oxidized as a result of water electrolysis, meaning that oxygen atoms had coated the surface of the nanotubes enabling the movement of water through the tube. Once the charge is reversed, oxidation stops and the water can no longer flow through the unoxidized portion of the tube.
The researchers also discovered that they could control the rate of water flow through nanotubes sitting directly next to each other, allowing one tube to pump quickly while the one next to it didn't pump water at all. Such an extreme difference in water absorption so close together is unprecedented, and could have major implications for time-released drug coatings, lab-on-a-chip devices, and water capture that mimics some of nature's most efficient water-harvesting materials.
The research is the first step to creating nanotube devices built to filter out specific elements from water and organic materials. With this enabling research in place, more efficient micro-filtration and separation techniques can be created for environmental restoration, the production of safe drinking water, biomedical research, and advanced circuitry.
Pulickel Ajayan, the Henry Burlage Professor of Materials Science and Engineering at Rensselaer and a world-renowned expert in fabricating nanotube materials, collaborated with Koratkar on this project. Four other Rensselaer researchers were involved with the research: Saroj Nayak, associate professor of physics; post-doctoral researcher Lijie Ci; and doctoral students Li Chen and Zuankai Wang.
Rensselaer Polytechnic Institute
A group of Rensselaer researchers led by Koratkar has found a way to use low-voltage electricity to manipulate the flow of water through nanotubes. Control of water's movement through a nanotube with this level of precision has never been demonstrated before.
"In this century one of the big challenges is how to get clean drinking water," Koratkar said. "If you can remove salt from water you can solve this problem. Nature does this all the time. The first step to getting to this process is to control the flow of water through nanochannels, which we have now successfully demonstrated. This is the starting part of the research. The next step would be to capture specific proteins, DNA, or impurities within the water with specifically designed nanotubes."
The researchers discovered that when the nanotube's membrane is given a small positive potential of only 1.7 volts, and the water is given a negative potential, the nanotubes quickly switch from repelling water to pumping water through the tube. When the charge on the water is raised, the water flows through at an exponentially faster rate. When the experiment is reversed with a negatively charged nanotube, it takes much higher voltage (90 volts) to move the water through the tube.
By simply reversing the polarity of the nanotubes, the team found that they could actually start and stop the flow of water through the tube. When a small positive charge is administered the water moves through the tube, and when that charge is reversed the water flow stops.
The researchers determined that the nanotube walls had been electrochemically oxidized as a result of water electrolysis, meaning that oxygen atoms had coated the surface of the nanotubes enabling the movement of water through the tube. Once the charge is reversed, oxidation stops and the water can no longer flow through the unoxidized portion of the tube.
The researchers also discovered that they could control the rate of water flow through nanotubes sitting directly next to each other, allowing one tube to pump quickly while the one next to it didn't pump water at all. Such an extreme difference in water absorption so close together is unprecedented, and could have major implications for time-released drug coatings, lab-on-a-chip devices, and water capture that mimics some of nature's most efficient water-harvesting materials.
The research is the first step to creating nanotube devices built to filter out specific elements from water and organic materials. With this enabling research in place, more efficient micro-filtration and separation techniques can be created for environmental restoration, the production of safe drinking water, biomedical research, and advanced circuitry.
Pulickel Ajayan, the Henry Burlage Professor of Materials Science and Engineering at Rensselaer and a world-renowned expert in fabricating nanotube materials, collaborated with Koratkar on this project. Four other Rensselaer researchers were involved with the research: Saroj Nayak, associate professor of physics; post-doctoral researcher Lijie Ci; and doctoral students Li Chen and Zuankai Wang.
Rensselaer Polytechnic Institute
Water Flow Current Events and Water Flow News RSSMIT scientists pinpoint origin of dissolved arsenic in Bangladesh drinking water
Researchers in MIT's Department of Civil and Environmental Engineering believe they have pinpointed a pathway by which arsenic may be contaminating the drinking water in Bangladesh, a phenomenon that has puzzled scientists, world health agencies and the Bangladeshi government for nearly 30 years.
Deep creep means milder, more frequent earthquakes along Southern California's San Jacinto fault
With an average of four mini-earthquakes per day, Southern California's San Jacinto fault constantly adjusts to make it a less likely candidate for a major earthquake than its quiet neighbor to the east, the Southern San Andreas fault, according to an article in the journal Nature Geoscience.
New insight into predicting cholera epidemics in the Bengal Delta
Cholera, an acute diarrheal disease caused by the bacterium Vibrio cholerae, has reemerged as a global killer. Outbreaks typically occur once a year in Africa and Latin America. But in Bangladesh the epidemics occur twice a year - in the spring and again in the fall.
Alfalfa sprouts key to discovering how meandering rivers form and maintain
Sinuous, meandering streams produce diverse and wildlife-rich habitats and are the aim of many river restoration efforts, but until now, the bank, water flow and sediment conditions required to form and maintain meanders have been largely a matter of speculation.
Web-based innovation improves, eases agricultural terrace design
A new internet-based tool for designing agricultural terraces promises to reduce the considerable labor involved and to optimize design by allowing rapid development of alternative layouts.
Salmon migration mystery explored on Idaho's Clearwater River
Temperature differences and slow-moving water at the confluence of the Clearwater and Snake rivers in Idaho might delay the migration of threatened juvenile salmon and allow them to grow larger before reaching the Pacific Ocean.
'Green Clean:' Researchers Determining Natural Ways To Clean Contaminated Soil
Researchers at North Carolina State University are working to demonstrate that trees can be used to degrade or capture fuels that leak into soil and ground water. Through a process called phytoremediation - literally a "green" technology - plants and trees remove pollutants from the environment or render them harmless.
Map characterizes active lakes below Antarctic ice
Lakes in Antarctica, concealed under miles of ice, require scientists to come up with creative ways to identify and analyze these hidden features.
GPS Helps Locate Soil Erosion Pathways
Grassed waterways are placed in agricultural fields where runoff water tends to concentrate because they can substantially reduce soil erosion.
Fish researcher demonstrates first 'non-visual feeding' by African cichlids
Most fish rely primarily on their vision to find prey to feed upon, but a University of Rhode Island biologist and her colleagues have demonstrated that a group of African cichlids feeds by using its lateral line sensory system to detect minute vibrations made by prey hidden in the sediments.
More Water Flow Current Events and Water Flow News Articles
 |
Where Cool Waters Flow by Randy Spencer (Author) Master Maine Guide Randy Spencer knows the lakes, streams, and woodlands around Grand Lake Stream, Maine like few others. He has learned the ways of the old Maine Guides - from the proper way to prepare shore lunches, to where to find the best salmon and bass, to how to survive in the wilderness - from some of the area's local legends. Now, in his first book, Where Cool Waters Flow, Randy puts you in the casting seat of his Grand Laker, introduces his many "sports" who come from miles away to decompress, brings you out on the trail during fall hunts, and takes you on many other adventures as only an insider can. |
 |
Flow How did a handful of corporations steal our water Starring: Maude Barlow, Vandana Shiva Directed By: Irena Salina Studio: Oscilloscope Pictures Release Date: 12/09/2008 Run time: 84 minutes |
 |
Petmate Deluxe Fresh Flow Pet Fountain Medium, Espresso by Petmate The Petmate Medium Fresh Flow filters, cools, adds oxygen, improves taste and reduces oder for your pets drinking water. The water circulates through a replaceable charcoal filter that removes contaminates and improves taste. The Fresh Flow uses a low voltage system for your pets safety. The non-skid rubber feet hold this 1.87 quart fountain in place on the floor. The fountain comes with one replaceable charcoal filter. The medium size is ideal for smaller dog breeds and cats it will give them a fresh drink every time. |
 |
Step2 Fun Flow Play Sink by Step2 Step2 Fun Flow Play SinkFill up on water play fun with this child sized play sink! The Fun Flow Play Sink features a battery-powered pump that keeps the water flowing through the gooseneck faucet (requires 2-D batteries NOT INCLUDED) and includes accessory play pieces like a cup, strainer, spinning waterwheel, and funnel. The faucet can rotate to direct water flow wherever desired within the sink bowl. The water pump has a built-in timer to save battery power. Minimal adult assembly required. Recommended for ages 2 and up. |
 |
Katadyn Vario Multi Flow Water Microfilter by Katadyn Katadyn Vario Microfilter The only water filter adjustable for different conditions. Combines the two best technologies ceramic and pleated microfiltration. Ultra fast flow (2 liters/minute). Replaceable carbon so water always tastes fresh. Microfiltration Method: Cleanable ceramic disc lengthens life of primary microfilter. 0.3 Micron high surface area pleated glassfiber microfilter removes waterborne bacteria and cysts. Replaceable carbon core reduces chemicals pesticides and bad taste in water. Output: Up to 2 quart (2 liter)/minute Cartridge Capacity: Up to 500 gallons (1875 liters) depending on water quality Weight: 15 oz Height: 6.5" Includes: Prefilter Deluxe Carry Bag and Cleaning Pad Mfg No: 8014931 Manufacturer: Katadyn |
 |
Alsons 655CBX 1.6 GPM Fluidics Showerhead, Chrome by Alsons Chrome . Showerhead Only . 1.6 GPM . Full Spray Pattern . Requires arm & flange . |
 |
12 each: Pet Mate Fresh Flow Pet Water Fountain Filter (24998) by Doskocil Mfg Co-Arlington Sold as one unit. (1 unit = 12 each.) 2 filters. For Petmate purifying pet water fountain Ace 8209702. Carded . Manufacturer number: 24998. SKU #: 8224008. Country of origin: China. Distributed by Doskocil Mfg Co-Arlington. |
 |
Centennial (Chapter Four): For As Long As the Waters Flow Starring: Sally Kellerman Directed By: Paul Krasny Also With: Richard Chamberlain (Primary Contributor) |
 |
Flow Water Kevin Coco (Primary Contributor) |
 |
Proform 67264 High Flow Aluminum Water Pump by Proform Water Pump |
| © 2009 BrightSurf.com |