News Release

New 'bi-molecule' with multiple technological applications discovered

University of Granada scientist discovers a new type of 'bi- molecule' that could help develop quantum sensors with multiple technological applications

Peer-Reviewed Publication

University of Granada

Dr. Rosario González-Férez

image: In the image, Rosario González- Férez, researcher at the Department of Atomic, Molecular and Nuclear Physics and the "Carlos I" Institute of Theoretical and Computational Physics of the UGR view more 

Credit: University of Granada

Dr. Rosario González-Férez, a researcher at the Department of Atomic, Molecular and Nuclear Physics and the "Carlos I" Institute of Theoretical and Computational Physics of the University of Granada, has published the article "Ultralong-Range Rydberg Bi-molecules" in the prestigious scientific journal Physical Review Letters. The results of the study show a new type of bi-molecule formed from two nitric oxide (NO) molecules, both in their ground state and in the Rydberg electronic state.

The work was made possible thanks to the scientific collaboration between the researcher and the Institute for Theoretical Atomic, Molecular and Optical Physics (ITAMP) at Harvard University. The study began during her stay at Harvard between March and July 2020, meaning that the entire process, from data-gathering and analysis to final written conclusions, was conducted during the Covid-19 pandemic. The stay, which was funded by the Fulbright Foundation and the Salvador de Madariaga programme of the Spanish Ministry of Science, Innovation and Universities, enjoyed the scientific collaboration of ITAMP's Hossein R. Sadeghpour and Janine Shertzer.

This new type of bi-molecule is the result of the union of two molecules of nitric oxide (NO) whose structure is arranged in such a way that the NO is located in one of the poles, while, in the other, is the NO + ion. The electron orbits around both, acting like a "glue" that binds this bi-molecule. In addition, its size corresponds to between 200 and 1,000 times that of NO, and its lifetime is long enough to enable its observation and experimental control, as these fragile systems are easily manipulated by means of very weak electric fields.

This type of bi-molecule enables researchers to implement and study chemical reactions at low temperatures from a quantum perspective and facilitates the investigation of intermolecular interactions at large distances, since they coexist at low temperatures.

Dr. González-Férez observes that the use of these bi-molecules in quantum technologies would be interesting both for the processing of information by entanglement and for the development of quantum sensors, with multiple technological applications in quantum optics and quantum computing.

González-Férez continues her work with two research groups, from the University of British Columbia in Canada and the University of Stuttgart in Germany, which aims to create this bi-molecule experimentally and confirm the theoretical predictions made over the last year.


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