IBM and University Researchers Create a Never-Before-Seen Molecule and Prove its Exotic Nature with Quantum Computing

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 IBM and University Researchers Create a Never-Before-Seen Molecule and Prove its Exotic Nature with Quantum Computing




An international team of scientists from IBM (NYSE: IBM), The University of Manchester, Oxford University, ETH Zurich, EPFL and the University of Regensburg have created and characterized a molecule unlike any previously known — one whose electrons travel through its structure in a corkscrew-like pattern that fundamentally alters its chemical behavior. Published today in Science, it is the first experimental observation of a half-Möbius electronic topology in a single molecule.

To the scientists’ knowledge, a molecule with such topology has never before been synthesized, observed, or even formally predicted. Understanding this molecule’s behavior at the electronic structure level required something equally fundamental: a high fidelity quantum computing simulation.

The discovery advances science on two fronts. For chemistry, it demonstrates that electronic topology — the property governing how electrons move through a molecule — can be deliberately engineered, not merely found in nature. For quantum computing, it is a concrete demonstration of a quantum simulation doing what it was designed to do: representing quantum mechanical behavior directly, at the molecular scale, to produce scientific insight that would otherwise have remained out of reach.

“First, we designed a molecule we thought could be created, then we built it, and then we validated it and its exotic properties with a quantum computer,” said Alessandro Curioni, IBM Fellow, Vice President, Europe and Africa, and Director of IBM Research Zurich. “This is a leap towards the dream laid out by renowned physicist Richard Feynman decades ago to build a computer that can best simulate quantum physics and a demonstration where, as he said, ‘There’s plenty of room at the bottom.’ The success of this research signals a step towards this vision, opening the door for new ways to explore our world and the matter within it.”

A Never-Before-Seen Molecule

The molecule, with the formula C₁₃Cl₂, was assembled atom-by-atom at IBM from a custom precursor synthesized at Oxford University, with individual atoms removed one at a time using precisely calibrated voltage pulses under ultra-high vacuum at near-absolute-zero temperatures.

Experiments with scanning tunneling and atomic force microscopy, both techniques pioneered at IBM, combined with quantum computing to reveal an electronic configuration with no counterpart in chemistry's existing record: an electronic structure that undergoes a 90-degree twist with each circuit, requiring four complete loops to return to the starting phase.

Global Energy Awards

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