An international team, including Oxford University scientists, has been investigating what happens to the top layer of atoms on the surface of a material. The material is strontium titanate – a complex metal oxide that many researchers are interested in because of its ability to split water into hydrogen and oxygen with sunlight, as well as its potential for use in electronic devices. An atomic model of the surface of strontium titanate. (Image: Oxford University) The team used a variety of techniques including scanning tunneling microscopy (STM) to directly ‘see’ the arrangement of surface atoms. Their observations reveal a series of structures with a surprisingly close and orderly arrangement. “In most materials, when you create a surface, the top layer of atoms rearrange to different positions from those in the rest of the material. This rearrangement of atoms is usually locked into a particular configuration that will minimize the surface energy,” said Dr. Martin Castell of Oxford University’s Department of Materials. “However, this is not the case for the surface of strontium titanate that we have been studying. This surface forms a whole family of different structures. Chemists would call these structures a homologous series - something that is routinely observed in the bulk of crystals, but not until now on the surface.” These ‘transformations’ could prove very important to researchers hoping to use strontium titanate in order to build new kinds of nanoelectronic devices or to grow thin films. The research also suggests that these techniques could make it possible to predict the surface structures of other oxides. “We have needed to use many different sophisticated experimental and theoretical approaches to solve this problem,” said Castell. “Our aim is to continue to work closely with our collaborators at Northwestern University in the United States to solve related materials problems.” The research was conducted by a team led by Castell of Oxford, as well as Laurence Marks and Ken Poeppelmeier, both professors at Northwestern University. For more information, visit: www.ox.ac.uk