Behind the discovery is Lars Samuelson, Professor of Semiconductor Physics at Lund University, Sweden, and head of the University’s Nanometre Structure Consortium. He believes the technology will be ready for commercialisation in two to four years’ time. A prototype for solar cells is expected to be completed in two years.
“When I first suggested the idea of getting rid of the substrate, people around me said ‘you’re out of your mind, Lars; that would never work’. When we tested the principle in one of our converted ovens at 400°C, the results were better than we could have dreamt of”, he says.
“The basic idea was to let nanoparticles of gold serve as a substrate from which the semiconductors grow. This means that the accepted concepts really were turned upside down!”
Since then, the technology has been refined, patents have been obtained and further studies have been conducted. In the article in Nature, the researchers show how the growth can be controlled using temperature, time and the size of the gold nanoparticles.
Recently, they have also built a prototype machine with a specially built oven. Using a series of ovens, the researchers expect to be able to ‘bake’ the nanowires, as the structures are called, and thereby develop multiple variants, such as p-n diodes.
A further advantage of the technology is avoiding the cost of expensive semiconductor wafers.
“In addition, the process is not only extremely quick, it is also continuous. Traditional manufacture of substrates is batch-based and is therefore much more time-consuming”, adds Lars Samuelson.
At the moment, the researchers are working to develop a good method to capture the nanowires and make them self-assemble in an ordered manner on a specific surface. This could be glass, steel or another material suited to the purpose.
The reason why no one has tested this method before, in the view of Professor Samuelson, is that today’s method is so basic and obvious. Such things tend to be difficult to question.
However, the Lund researchers have a head start thanks to their parallel research based on an innovative method in the manufacture of nanowires on semiconductor wafers, known as epitaxy – consequently, the researchers have chosen to call the new method aerotaxy. Instead of sculpting structures out of silicon or another semiconductor material, the structures are instead allowed to develop, atomic layer by atomic layer, through controlled self-organisation.
The structures are referred to as nanowires or nanorods. The breakthrough for these semiconductor structures came in 2002 and research on them is primarily carried out at Lund, Berkeley and Harvard universities. The Lund researchers specialise in developing the physical and electrical properties of the wires, which helps create better and more energy-saving solar cells, LEDs, batteries and other electrical equipment that is now an integrated part of our lives.
The article ‘Continuous gas-phase synthesis of nanowires with tuneable properties’ can be found by entering “I 10.1038/nature11652” here: http://dx.doi.org/.
Besides Lars Samuelson, the other authors of the article are: Magnus Heurlin, Martin Magnusson, David Lindgren, Martin Ek, Reine Wallenberg and Knut Deppert, all employed at Lund University, except for Martin Magnusson, who works at start-up company Sol Voltaics AB.
The research has been funded by the Swedish Research Council, the Swedish Foundation for Strategic Research (SSF), the Knut and Alice Wallenberg Foundation and Vinnova.
Lund University Nanometre Structure Consortium, nmC@LU: www.nano.lth.se.
High-resolution photographs of Lars Samuelson are available in the Lund University image bank: https://bildweb.srv.lu.se/login/. Log in with username ‘press’ and password ‘press’, then enter the name into the search field. For a photograph of all the authors and an illustration of the production process, search for “aerotaxy”.
For an animation of the production process, see: http://www.youtube.com/watch?v=Bhdr8z8d-Lo.
Semiconductors are materials that neither conduct electricity as well as metals, nor stop a current as effectively as insulators – silicon and germanium are two examples. These properties may not sound attractive, but in actual fact they are excellent. The reason is that we can influence the conductive capacity of the materials, for example by introducing impurity atoms, known as doping. Materials with different types of doping can be combined to manufacture products such as transistors, solar cells or LEDs.