Product Description

Enthusiasts look forward to a time when tiny machines reassemble matter and process information with unparalleled power and precision. But is their vision realistic? Where is the science heading? As nanotechnology (a new technology that many believe will transform society in the next one hundred years) rises higher in the news agenda and popular consciousness, there is a real need for a book which discusses clearly the science on which this technology will be based. Whilst it is most easy to simply imagine these tiny machines as scaled-down versions of the macroscopic machines we are all familiar with, the way things behave on small scales is quite different to the way they behave on large scales. Engineering on the nanoscale will use very different principles to those we are used to in our everyday lives, and the materials used in nanotehnology will be soft and mutable, rather than hard and unyielding. "Soft Machines" explains in a lively and very accessible manner why the nanoworld is so different to the macro-world which we are all familiar with. Why does nature engineer things in the way it does, and how can we learn to use these unfamiliar principles to create valuable new materials and artefacts which will have a profound effect on medicine, electronics, energy and the environment in the twenty-first century. With a firmer understanding of the likely relationship between nanotechnology and nature itself, we can gain a much clearer notion of what dangers this powerful technology may potentially pose, as well as come to realise that nanotechnology will have more in common with biology than with conventional engineering.

Product Details

• Amazon Sales Rank: #198147 in Books
• Published on: 2007-11-29
• Original language: English
• Number of items: 1
• Binding: Paperback
• 238 pages

From the Author
Soft Machines – Nanotechnology and Life
By Richard A.L. Jones

A brief introduction.

There’s probably no technology that’s more debated, more discussed and more misunderstood right now than nanotechnology. I wrote Soft Machines to explain just what nanotechnology is now and what it will be in the future. Will it lead to a new form of artificial life that’s ultimately going to replace us? Or is it just a new and trendy name for chemistry and materials science?

Nanotechnology, to some people, is the new technology that’s going to revolutionize the world. Tiny robots, each no bigger than bacteria, will be able to make anything from any ingredients; they’ll end poverty and make the environment pristine again. Enthusiasts imagine tiny submarines, like the one in that 60’s science fiction film Fantastic Voyage, able to swim around in our bloodstreams, curing all illnesses, maybe even allowing people to live for ever.

But every utopia has its dark side, and some people fear that if we can make these nanobots, they may get out of our control. Michael Crichton’s new thriller "Prey" illustrates this possibility chillingly and when the film is released this autumn I’m sure we’ll hear much more about this. The ultimate catastrophe is if the nanobots reproduce out of control, eating everything and turning the world into GREY GOO!

Many scientists, technologists and business people think that both the utopia and the dystopia are just the stuff of science fiction, great for thrillers but nothing to worry about in the real world. To them nanotechnology is a business opportunity. We’ll be able to control matter on the atomic scale, but rather than making nanobots, we’ll just make better sunscreen, stain resistant trousers and other mundane but lucrative products.

The man who invented nanotechnology, the word nanotechnology, was K. Eric Drexler in a best selling book published some 15 years ago called "Engines of Creation". He argued that we know it must be possible to make nanobots because life itself is made of them – all the tiny machines in our cells and in the cells of all living things are working examples of natural nanotechnology. So if we could make artificial versions of these nanomachines we would have nanotechnology. But we would make the machines not from the soft squidgy materials of biology but from hard, strong materials like diamond. So we’d be making something like life but stronger and tougher and more durable. That’s why we would have to worry that this new artificial type of life might replace the old, soft and squidgy version.

I think that Drexler is half right. It must be possible to make nanomachines because we know that nature does it. But what if nature uses soft and squidgy stuff because that’s what works best? A car might be faster and stronger than a horse, but is it necessarily so that diamond nanobots are tougher than bacteria. The more I thought about it, the more I realised that nature uses squidgy materials because on the tiniest of length scales that’s what works best. The physics of small things is different to the physics of big things, and when you design for the nanoscale you need to take that into account.

My book explains why nanoscale machines need to be soft machines, like the machinery of life, rather than the machinery of cogs and gears, of the macroscopic world. It explains why life is the way it is, and that if we want to make nanobots we should copy nature and make them soft. It is this kind of soft nanotechnology that could lead to all sorts of advances, like new life saving and life enhancing treatments in medicine, super-fast computers, and cheap and clean renewable energy from the sun.

And what about grey goo? As we understand just how clever and appropriate nature’s nanoscale designs are, I think we’ll be a little less cocky about able to design something better ourselves. Soft Machines describes how we might go about copying nature in nanotechnology, but it’s going to be a very long time before we can surpass nature.

About the Author
Richard A. L. Jones became Professor of Physics at the University of Sheffield in 1998.

Customer Reviews

A good introduction
The book wasn't quite what I was looking for - but I still found it of interest. It's aimed more at the the type of person that has an interest in biology, and the potential for therapeutic application of nanotechnology. However, I felt that it missed out on a number of key points - I would suggest combining this book with the work by Drexler for a better understanding of the subject.