Skip to main content
To KTH's start page To KTH's start page

Study shows faster, scalable way to make molecular semiconductors

A nano-scale view of a molecular junction created with a new, scalable method reported in Nature Communications by researchers at KTH.
Published Oct 16, 2018

Visions for what we can do with future electronics depend on finding ways to go beyond the capabilities of silicon conductors. The experimental field of molecular electronics is thought to represent a way forward, and recent work at KTH may enable scalable production of the nanoscale electrodes that are needed in order to explore molecules and exploit their behavior as potentially valuable electronic materials.

A team from the Department of Micro and Nanosystems  at KTH recently tested a technique to form millions of viable nanoscale molecular junctions – extremely small pairs of electrodes with a nanometer-sized gap between them, where molecules can be trapped and probed. The findings were published in Nature Communications .

Shyamprasad Natarajan Raja

The KTH researchers reported that with a 100 mm diameter wafer of thin materials, they can produce as many as 20 million such electrodes in five hours’ time, using gold film on top of a brittle material that forms cracks. In addition, working with the van der Zant Lab at TU Delft, the team trapped and studied a widely-used reference molecule in the nanometer-wide space between the electrodes to ensure that the fabrication method didn’t hinder the formation of molecular junctions.

Shyamprasad Natarajan Raja , one of the co-authors, says this “crack-defined break junction” method offers a breakthrough to the impasse of scalable production of structures that could one day enable electronic devices made of single molecules.

PhD, master thesis or intership at Micro and Nanosystems

All about the opportunities for PhD and Master's students in the MST Lab.

The key is to produce gaps that enable a phenomenon called tunneling, in which electrons overcome the break in a circuit. A break junction has a gap the size of a few atoms, which breaks the flow of electrons through it. However, because the gap is so small, electrons with sufficient energy can still jump across this expanse. Tunneling electrons sustain a small but measurable current that is extremely sensitive to the size of the gap – and to the presence of nano-objects inside it.

Ask a Master's student

Nanotechnology Master's student Saumey Jain and others studying nanotechnology at KTH are available to take your questions. Send them a question now. 

“Break junctions are the best means available to make single molecules part of a larger electronic circuit that can probe molecules,” Raja says. They could also one day enable ultra-sensitive high-speed detectors using quantum tunneling, he says.

However, tunneling break junctions are produced one gap at a time, which has been a major roadblock in developing any application involving tunneling junctions outside a research laboratory,” Raja says.

The method begins with using photo lithography to pattern a stack of gold on titanium nitride (TiN). This stack is set on a silicon wafer, and the notched structures that are formed then concentrate stress. So, when the silicon directly underneath the stack is removed (a process called release etching), tiny cracks form at the pre-determined locations in the TiN to release the stress. This in turn deforms the gold, stretching it into atomically thin wires running across these cracks, which upon breaking form gaps as small as a molecule.

Raja says that the method can be used for other conductive materials, besides gold, which offer interesting electrical, chemical and plasmonic properties for applications in molecular electronics and spintronics, nanoplasmonics and biosensing.

Financial support for the research was provided by the Swedish Research Council (Grant No. 2016-04852) and the European Research Council (Grant No. 277879 and No. 812975).

The full article can be read at  

A recent review on the scalable manufacturing of nanogaps can be read at

David Callahan