Article courtesy of S Ananthanarayanan | March 9, 2016 | The Statesman | Shared as educational Material on Scrubbing clean water.
Industry, pollution and the growing population together increasingly constitute both the demand for and scarcity of clean water. While river-fed sources are becoming less accessible, groundwater is also sinking deeper or getting contaminated.
Marc Andelman, Massachusetts-based inventor, Professor Tony Cass from Imperial College, London, and Professor Sung Jae Kim from Seoul National University presented three new nano technology-based solutions for extracting potable water from inferior sources at the eighth India Nano Meet organised by the S&T Promotion Society, government of Karnataka, at Bengaluru on 8 March. The packed audience was of industrialists, start-ups and students and Professor T Pradeep of IIT, Chennai, who conducted the meeting, pressed for emerging technology to be picked up and used for the benefit of the country and the world.
Andelman’s innovation is an improvement of the method called capacitative de-ionisation, or CDI, where a pair of oppositely charged surfaces, the electrodes, fish out contaminants, mainly salt, from water that is made to flow between the charged plates. The voltage used is low, and there is no current between the surfaces, but dissolved contaminants, which are split in the water medium into oppositely charged halves called ions drift to opposite ends till the ends collect full charge and their drifting stops. While the water that flows through gets purified when the charge is on, the surfaces can now be discharged to release a concentrate of contaminants for disposal. CDI, which extracts dissolved contaminants, is energy efficient compared to other methods like distillation or the now common Reverse Osmosis, which work the other way about, extracting water from a salt solution.
Andelman explained that the material of the electrodes had to be porous so that there was high surface area and greater capacity to collect charge for the same voltage applied. A limitation of the basic design, however, was that when charged ions of the contaminant piled up very near the electrodes, oppositely charged ions were also inserted into the region just beyond, a region called the diffuse layer, and this reduced the efficiency of the extraction of contaminants. A first improvement has hence been to insert an ion exchange membrane that would not impede the movement of the contaminant ions but act as a barrier to the counter-current of opposite charges. This did improve efficiency, but the membrane is expensive and takes space in the water channel.
Andelman’s innovation was to replace the membrane by directly coating the electrodes with a material that contained charged components that were drawn, half towards and half away from the charge on the electrodes. These separated charges create a layer that behaves like the ion exchange charge barrier in keeping down the counter-current of charges being released from the electrodes. This treatment, of creating a “polarised electrode”, however, is a low-cost procedure and the electrodes themselves are nano-porous carbon, which could come from burnt coconut shells, Andelman said.
Professor Tony Cass, chemical biologist, explained that arsenic poisoning of ground water, which was notorious in Bangladesh, was in fact a problem the world over. And the great difficulty in its management was the complexity of detection and measurement. It was, hence, a challenge to monitor large numbers of water borings, particularly as arsenic levels could change within a very short period of time. “You cannot manage anything till you can measure it,” Professor Cass said, citing a remark made about air pollution in London.
He said the current methods of measuring sugar levels in blood and urine of diabetics became an example to emulate in assessing arsenic levels. Testing for sugar used to be slow and cumbersome 30 years ago but it could now be done very easily, and fast, with a hand-held device by the patient. The secret of the advance was the discovery of an enzyme that reacted with glucose, and exclusively with glucose, to set free an electron, that formed a current that could be measured by a meter or a counter. A light pinprick to access the blood could then be automated to read out the glucose level, in a device that was now sold over the counter! And there is a strip of paper that can be dipped in urine and the colour shows the level of glucose.
Professor Cass, with his colleagues Joanne Santini and Thomas Osborne, chanced upon a similar action of an enzyme that set electrons free while changing arsenic salts from one form to another. They have now devised a method to build a simple instrument, like the glucometer for diabetics, which measures low levels of arsenic in water with good accuracy. “The device is not so good at high concentrations,” he says, “but fortunately the area of interest is low contamination.”
Professor Sung Jae Kim takes inspiration from coastal mangroves that flourish in salt seawater to devise ways of desalination as a source of fresh water for human consumption or irrigation. The current ways of largescale desalination are only distillation or reverse osmosis, both of which are power intensive. It is, hence, attractive to desalinate without the use of power, except sunlight, maybe, like nature.
The process of osmosis is that when solutions of different concentration are separated by a semi-permeable membrane, which lets through the solvent but not the solute, the solvent is driven to pass from the lower concentration to the higher side. This driving force, in fact, can support a higher column of greater concentration, which is what happens in a coastal freshwater well, which supports the pressure of salty sea water whose level is higher. In reverse osmosis, physical pressure that is greater than the pressure of osmosis is exerted on the side of higher concentration to drive the solvent, water in the case of brine, to the freshwater side.
The roots of coastal plants, which stand in salt water, are able to keep out the salt and take in fresh water, which then rises with the sap to the stem and leaves, using capillary forces. The work of Professor Sung Jae Kim and colleagues identifies the role of capillaries, or very narrow channels, in attaining the separation of higher and lower concentrations, or an “ion concentration polarisation”, leading to an “ion depletion zone” near nano-porous materials that is selectively permeable. A device based on this effect has been found to achieve 90 per cent reduction of salinity without an external power source. The group has carried out theoretical analysis and has come to a conclusion of methods to commercialise the process.
Getting to the market
Professor T Pradeep spoke of the scale of the problem of water, which would soon dwarf other crises that humanity faces. A very low level of contamination, just one part in 1013, which works out to “one person in 10,000 times the Indian population”, he said, rendered water unfit for use. To purify water affordably and on a large scale was, hence, a priority. There was a case to create an institution to support research and to help ideas to be quickly commercialised, he said. But Andelman later observed that “there is zero R&D money in the USA for water tech, neither government nor corporate”. and he funded his own research by running a side business!