Different isotopes of the same element don’t always behave identically in chemical reactions. As a result, naturally occurring samples can have measurably different ratios of stable isotopes. In most observed isotope fractionation, deviations in reactivity vary with the mass difference between isotopes, due either to kinetic effects or to differences in the zero-point vibrational energy of chemical bonds. Last year Bridget Bergquist and Joel Blum of the University of Michigan in Ann Arbor found that photochemical reactions of mercury can result in isotope fractionation that does not fit the mass-dependent pattern: Odd-numbered Hg isotopes behave differently from even-numbered ones. Such mass-independent fractionation, observed in only a few elements so far, may be due to spin–spin interactions between nuclei and the unpaired electrons created in light-initiated reactions. Now, Abir Biswas, working with Blum and other Michigan colleagues, has found that Hg stored in coal deposits shows the effects of both mass-dependent...
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1 December 2008
December 01 2008
Citation
Johanna L. Miller; Tracking mercury by its isotopes. Physics Today 1 December 2008; 61 (12): 25–26. https://doi.org/10.1063/1.4796736
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