In some heavy atoms like bismuth (crystalline form), electrons move at relativistic speeds
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Albert Einstein’s special theory of relativity has reshaped our understanding of chemical bonds within molecules, a phenomenon now observed for the first time by researchers.
Special relativity elucidates how moving at near-light speeds affects the experience of space and time, extending even to electrons within certain heavy atoms. These high-speed electrons behave similarly to those found in particle accelerators and spacecraft.
Wang Laisheng and colleagues at Brown University in Rhode Island undertook a groundbreaking study that challenges conventional views on chemical bonding in charged molecules composed of bismuth and carbon.
In the studied molecule, bismuth and carbon are interconnected via three bonds. Researchers anticipated one bond would be of the “sigma” type while the other two would be “pi” bonds. The distinction between these bond types is rooted in the quantum nature of electrons, which are not solid masses but are instead “smeared” over a space, determining bond formation based on their spatial overlap.
During experiments, Wang and his team mapped electron distributions across the molecule, analyzing its bonding configuration. Contrary to expectations, they found the electron distributions indicative of two unique combinations of sigma and pi bonding shapes. “These bonds exhibit characteristics inconsistent with traditional definitions,” Wang notes. “They defy conventional Sigma and Pi classifications.”
His collaborator, Kirk Peterson, from Washington State University, calculated that this unusual mix arises from strong electromagnetic interactions, where electrons near the bismuth nucleus exhibit relativistic speeds—a phenomenon never before captured experimentally.
“Studying heavy elements presents unique challenges; quality experimental data is scarce,” Peterson mentions. “It’s a rare opportunity to compare advanced theoretical models with empirical data in such a fascinating way.”
Wang emphasized that key to their success was cooling the molecules before observation, significantly reducing noise and excitation, leading to more accurate results.
“The methodology employed is the pinnacle of both experimental and theoretical research,” states Pekka Pyykkö from the University of Helsinki, Finland.
This relativistic restructuring of bismuth-carbon bonding could revolutionize how organobismuth compounds are utilized in chemical reactions. Indeed, recent studies from the Max Planck Institute for Coal Research in Germany demonstrate that relativistic effects enhance the catalytic properties of this heavy metal in chemical processes.
Professor Wang and his team aim to replicate this experiment using a similar element from the periodic table to investigate when special relativity disrupts traditional chemical bond structures.
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Source: www.newscientist.com












