An international consortium led by researchers at the University of Basel has developed a method to precisely alter the quantum mechanical states of electrons within an array of quantum boxes. The method can be used to investigate the interactions between various types of atoms and electrons, which is essential for future quantum technologies, as the group reports in the journal Small.

Applications of quantum mechanics are often compromised by the fundamental property of quanta: any measurement inevitably modifies the measured state. Technologies such as quantum computers can be designed only on the basis of known, clearly defined and simple interactions between individual components.

The Department of Physics at the University of Basel together with the Swiss Nanoscience Institute has now developed a method that can be used to study these kinds of interactions in a well-defined system.

Similar to a breadboard in electrical engineering
Breadboards are used in electronic measurement technology to design and test prototypes of electronic circuits and for teaching purposes. The procedure developed by the international consortium led by Prof. Thomas Jung of the University of Basel works in a similar way: for the first time, the new method allows researchers to configure a network of quantum boxes in order to form various quantum electronic states.

A quantum box is an artificially produced structure that restricts a particle's movements, so that it can move in only two dimensions. This reduces the complexity of a particle interaction and simplifies the process of measurement and analysis.

The research team refined an established method in which atoms are repositioned one after the other using scanning tunneling microscopy, allowing the creation of clearly defined quantum sys-tems. Through the targeted relocating of xenon atoms in quantum boxes, the team succeeded in generating different patterns that correspond to a wide range of quantum states.

Essential tool for quantum technology
The development of quantum technology relies on a detailed understanding of the interdependence between different electronic states; for example, in various atoms.

With the physicists' method, quantum states can be accurately reproduced and interactions between various chemical elements and well-defined electronic states examined - an "unlimited playing field for the study of quantum states", as the researchers write in Small.

A range of institutions contributed to the project's success: the theory was outlined by researchers from Linkoping (Sweden), the molecules used were synthesized in Heidelberg (Germany), and scientists from San Sebastian (Spain) were responsible for some of the complex measurements of the specific quantum states.

Sylwia Nowakowska, Aneliia Wackerlin, Ignacio Piquero-Zulaica, Jan Nowakowski, Shigeki Kawai, Christian Wackerlin, Manfred Matena, Thomas Nijs, Shadi Fatayer, Olha Popova, Aisha Ahsan, S. Fatameh Mousavi, Toni Ivas, Ernst Meyer, Meike Stohr, J. Enrique Ortega, Jonas Bjork, Lutz H. Gade, Jorge Lobo-Checa, and Thomas A. Jung - Configuring Electronic States in an Atomically Precise Array of Quantum Boxes - Small 2016,00, 1-6 | doi: 10.1002/smll.201600915