The achievement falls short of actual alchemy, but the silver ‘super atoms’ recently created by TU Delft researchers have turned the periodic table of elements on its head. “This research is leading to a whole new branch of chemical engineering.”
Tomas van Dijk
“A modern form of alchemy? Well yes, in a certain sense we are creating new atoms, so-called super atoms, but we’re not going to create gold. Our work focuses on entirely new types of matter, such as crystals with new, special magnetic, optical, or electrical properties. It’s fascinating. Our research is leading to a whole new branch of chemical engineering, cluster chemistry.” Professor Dr Ir. Andreas Schmidt-Ott, of the Faculty of Applied Physics, can’t hide his enthusiasm when discussing this research. Together with Dr Christian Peineke, who recently earned his doctorate degree under Schmidt-Ott’s supervision, the professor has developed a technique that will enable him to create atomic clusters, called ‘super atoms’, from metals that mimic the properties of elements in the periodic table. Depending on their size and charge, the particles for example can behave like inert gases, or like halogens such as iodine or chlorine.
More importantly, the two scientists managed to capture the particles in a very pure state, without any contamination, and select them according to size, ready to be used in chemical experiments. This was something that American researchers who achieved fame some years ago when they created aluminium super atoms, could only dream of, as they were unable to lay their hands on sufficient quantities of pure super atoms. According to Schmidt-Ott, the way forward now lies open for cluster chemistry.
Magic numbers
A small twisted wire, just like the filament in an incandescent bulb, but made of silver, forms the basis for the special silver particles. “If you heat this silver wire up to about nine hundred degrees Celsius – just below its melting point – you create a vapour of silver atoms,” Peineke explains, as he gives a tour of his laboratory at DelftChemTech. Like water molecules forming into fog, the floating atoms stick together in clusters; but unlike fog, they don’t do this at random. For example, clusters of silver containing 9, 13, or 55 atoms turn out to be highly energetically stable, and consequently appear in conspicuously large numbers in the mist of silver. These are the magic numbers.
The mechanism underlying the stability of super atoms with magic numbers was described in some detail in Science magazine in 2005 by American researchers at Virginia Commonwealth University. They had already discovered metal super atoms, but theirs were made of aluminium rather than silver. Their aluminium clusters of 13, 23, and 37 atoms behaved just like solitary atoms, because they had electrons that circled the entire atom cluster. These so-called ‘shells’ showed a remarkable resemblance to the shells of elements from the periodic table. It was the spatial arrangement of the atoms, combined with these super atom shells, that made the particles so stable.
After performing calculations on the spatial structure and the distribution of the electrical charges of the clusters, the researchers concluded that there had to be a whole range of other large and small clusters that were stable. They also discovered that their aluminium 13 exhibited special properties if it had an iodine atom attached to it, as this created several electrically charged regions that made the cluster eminently suitable for use as a catalyst. The super atoms add a third dimension to the periodic table is what several popular science magazines reported at the time. Schmidt-Ott shares that opinion, although he adds that the third dimension still needs to be mapped:
“The super atoms found so far share chemical properties with elements from the periodic table because their shells are similar. It is not unthinkable that we will find atoms with other shells that will give us entirely new properties. Those are the super atoms that form the third dimension.” In future, Schmidt-Ott hopes to discover such atom clusters with new special magnetic, optical, or electrical properties that at the same time will be so stable that they can be used to create crystals or other solids. The turn of the last century saw the discovery of the ‘buckyball’, a spherical, hollow super atom with remarkable electrical properties and made up of sixty carbon atoms. “There are probably many more super atoms out there that are equally stable, waiting to be discovered,” the professor adds. It is improbable that any structures even more spectacular than buckyballs will be discovered. “Clusters of fewer than one hundred atoms offer the best prospects, as it makes a real difference to the chemical properties of those particles whether you add an atom or take one away,” says Schmidt-Ott, who himself focused on particles up to nine atoms in size.
The spiritual father of the aluminium super atoms, Professor Shiv Khanna of Virginia Commonwealth University, has high expectations for TU Delft’s efforts.
He sees many applications for his aluminium super atoms:
as catalysts in fuels, for example, or in the form of superconducting crystals, but he has had little opportunity to experiment with the particles, which until recently remained elusive. Now that the technique developed by TU Delft is available, the days of modelling are over, and actual experiments can begin.
Until recently, super atoms were primarily created in a vacuum, using so-called cluster beams. In this process, particles are produced by means of condensation of a damp, and immediately sucked into a mass spectrometer for analysis. Although this type of technique allows the particles to be observed, after doing so they cannot be used for any other purpose. Schmidt-Ott and Peineke however have managed to capture the particles under normal pressure in an inert gas, called argon, and then to accurately sort them according to size, both of which are prerequisites for any further experimental work.
“Our filament technique makes use of small positive charges in the super molecules,” Peineke explains. “We use argon gas to feed the particles through a capacitor. As we apply a voltage to that, the particles veer to one side because of their charged state. The bigger they are, the more resistance the gas offers and the less the particles are deflected. By varying the voltage we can effectively sort them by size and collect them.”
“This is a graph showing the clusters made by means of this mobility analysis,” Schmidt-Ott says. “At first all we saw were small spikes that hardly seemed significant. Then we compared the graphs of many tests, and in each case the spikes showed up in the same spot. We had discovered the magic numbers of silver. Together with a French colleague, Dr Michel Attoui, we refined the technique by lowering the temperature and using more sensitive equipment.” Khanna, Peineke and Schmidt-Ott are now collaborating on an article about silver super atoms. “The research on super atoms has now become a joint effort,” Khanna says. This is confirmed by Schmidt-Ott: “They can do calculations on super atoms and predict certain properties. We can then use our technique to supply on demand any particles that look promising.”
Ironically, Schmidt-Ott and Peineke owe their success to a contamination of the silver filaments with potassium. It was this impurity that ensured that the particles could be sorted by size. “Silver always contains traces of potassium,” Schmidt-Ott says. “As the filament heats up, potassium ions are released which then attach themselves to the silver clusters. It is these atoms that give the silver a slight positive charge. They hardly affect the stability and the electrical properties of the super atoms, while at the same time enabling us to separate the super atoms later on. In a similar way we can also make aluminium super atoms. The only thing we have to do is to add some potassium to the filament, or caesium, which we will also be experimenting with. The technique remains the same. We discovered it all purely by chance.”