Skip to main content

The Nanotechnology Myth – Brian Clegg

Imagine an army of self-replicating robots, each invisibly small, endlessly reproducing, forming a grey mass that swamps the world, and destroys its resources. This was the premise of Michael Crichton’s thriller, Prey, but the concept of using invisibly small technology is not just science fiction. This so-called ‘grey goo’ scenario is fantasy (grey goo because the nanobots are too small to be seen individually, and would collectively appear as a viscous, self-moving grey liquid). But nanotechnology is real and has a huge potential.
Until recently, that prefix ‘nano’ was an unfamiliar one. At the 11th Conférence Générale des Poids es Mesures in 1960 a faceless committee defined the SI (Système International) units. As well as agreeing standards of measurement like the meter, the kilogram and the second, the conference developed a range of prefixes for bigger and smaller units from tera (multiply by 1,000,000,000,000) to pico (divide by 1,000,000,000,000). The penultimate prefix was nano, (divide by 1,000,000,000), derived from nanos, the Greek word for a dwarf. One billionth, a truly tiny scale.
Twenty-six years later, American author K. Eric Drexler combined “nano” with “technology” in his book Engines of Creation. Although Drexler outlined a wide range of possibilities for products smaller than a microbe, the majority of the book focuses on molecular manufacturing, using nanomachines to assemble objects at the molecular level, a concept first suggested by physicist Richard Feynman. A single assembler working at this scale would take thousands of years to achieve anything –assembly would require trillions of nanomachines. Drexler speculated that this would require nanomachines that could replicate like a biological creature, leading to the vision of grey goo and Crichton’s Prey.
Real nanotechnology does not involve anything so complex as an assembler. One very limited form of nanotechnology is already widely used – nanoparticles. Substances reduced to particles on this scale have a very different physical behaviour to normal materials. The most common use of nanotechnology currently is sunscreens, where nanoparticles of zinc oxide or titanium dioxide are used to protect us from the sun’s rays, allowing visible light to pass through, but blocking harmful ultraviolet. In fact we have used nanoparticles unwittingly for centuries in some of the pigments used in pottery glazing.
A more recent development is to use nanotechnology in the form of films of material that are around a nanometre in thickness. We’ve seen this in the lab with graphene, the amazing new form of carbon developed at the University of Manchester, which looks to have huge potential, but nano-coatings are already employed in the real world, protecting everything from mobile phones to footwear from liquids.
Being nanotechnology makes all the difference to the protective films produced by UK manufacturer P2i, based on research originally undertaken at Durham University. Their incredible thinness makes them ideal for this purpose because the polymer coating is not noticeable to the user –visibly or to the touch – and can be used to treat an electronic device inside and out or to cling to the fibres of clothing and footwear. The coating is applied using plasma in a vacuum chamber, bonding it to the surface, as this video demonstrates:
A little further down the line are nanotubes and fibres. Often made of carbon, these molecular filaments are grown rather than constructed and have the capability both to provide super-strong materials (as an extension of the current cruder carbon fibres) and incredibly thin conductors for future generations of electronics. Semi-conducting nanotubes have already been built into (otherwise) impossibly small transistors, while carbon nanotubes could make one of the more remarkable speculations of science fiction a reality.
Writer Arthur C. Clarke conceived of a space elevator, a 100,000 kilometre cable stretching into space that could haul satellites and space craft out beyond the Earth’s gravity without the need for expensive and dangerous rocketry. Bradley Edwards, working for the NASA Institute of Advanced Concepts commented in
Nanotubes (image from NASA)
2002: “[With nanotubes] I’m convinced that the space elevator is practical and doable. In 12 years, we could be launching tons of payload every three days, at just a little over a couple hundred dollars a pound.” Clearly his timescales were way out – but the concept is still amazing.
Today’s practical applications of nanotechnology derive largely from the special properties of small assemblies of atoms, but nanotechnology has one other incredible trick up its sleeve: quantum theory. At the scale of an atom, physics operates by rules that are entirely different to the familiar world. The counter-intuitive nature of quantum behaviour, from single particle interference to tunnelling opens up new possibilities for the technology of the very small.
Perhaps the best example of nanotechnology showing the promise of quantum effects is plasmonics. Something remarkable happens if, for example, light is shone on a gold foil peppered with millions of nanoholes. It seems reasonable that only a tiny fraction of the light hitting the foil would pass through these negligible punctures, but in fact they act like funnels, channelling all the light that hits the foil through the sub-microscopic apertures. This bizarre phenomenon results from the interaction between the light and plasmons, waves in the two dimensional ocean of electrons in the metal.
The potential applications of plasmonics are dramatic. Not only the more obvious optical ones – perfect lenses and superfast computers that use light (photonics) rather than electrons to function – but also in the medical sphere to support diagnostics, by detecting particular molecules, and in drug delivery. Naomi Halas of Rice University in Texas envisions implanting tiny cylinders containing billions of plasmonic spheres, each carrying a minuscule dose of insulin. Infra red light, shone from outside the body, could trigger an exact release of the required dose. ‘Basically, people could wear a pancreas on their arm,’ said Halas.
Nanotechnology may be scary in fiction, but away from the mythology it has an awful lot to offer.

Comments

Popular posts from this blog

The Dialogues - Clifford Johnson ***

The authors of science books are always trying to find new ways to get the message across to their audiences. In Dialogues, Clifford Johnson combines a very modern technique - the graphic novel or comic strip - with an approach that goes back to Ancient Greece - using a dialogue to add life to what might seem a dry message.

We have seen the comic strip approach trying to put across quite detailed science before in Mysteries of the Quantum Universe. As with that book, Dialogues manages to cover a fair amount of actual physics, but I still feel that the medium just wastes vast acres of page to say very little at all. This is brought home here because quite a lot of the sections of Dialogues start with several pages with no text on at all, just setting up the scenario.

As for using a discussion between two people to put a message across, Johnson makes the point that, for instance, Galileo's very readable masterpiece Two New Sciences is in the form of a dialogue (more accurately a discu…

Liam Drew - Four Way Interview

Liam Drew is a writer and former neurobiologist. he has a PhD in sensory biology from University College, London and spent 12 years researching schizophrenia, pain and the birth of new neurons in the adult mammalian brain. His writing has appeared in Nature, New Scientist, Slate and the Guardian. He lives in Kent with his wife and two daughters. His new book is I, Mammal.

Why science?

As hackneyed as it is to say, I think I owe my fascination with science to a great teacher – in my case, Ian West, my A-level biology teacher.  Before sixth form, I had a real passion for the elegance and logic of maths, from which a basic competence at science at school arose.  But I feel like I mainly enjoyed school science in the way a schoolkid enjoys being good at stuff, rather than it being a passion.

Ian was a revelation to me.  He was a stern and divisive character, but I loved the way he taught.  He began every lesson by providing us with a series of observations and fact, then, gradually, between …

Ten Great Ideas About Chance - Persi Diaconis and Brian Skyrms ***

There are few topics that fascinate me as much as chance and probability. It's partly the wonder that mathematics can be applied to something so intangible and also because so often the outcomes of probability are counter-intuitive and we can enjoy the 'Huh?' impact of something that works yet feels so far from common sense.

I think I ought to start by saying what this is isn't. It's definitely not an introductory book - the authors assume that the reader 'has taken a first undergraduate course in probability or statistics'. And though there's an appendix that claims to be a probability tutorial for those who haven't got this background, it's not particularly reader-friendly - in theory I knew everything in the appendix, but I still found parts of it near-impossible to read.

As for the main text, if you pass that first criterion, my suspicion is that, like me, you will find parts utterly fascinating and other parts pretty much incomprehensible. Th…