-
March 14, 2011 - Volume 89, Number 11
- p. 38
Science & Technology Concentrates
More Science & Technology Concentrates
- Fluoride Blocks For Enzyme
- Blocked active site allows scientists to visualize enzyme-inhibitor complexes that couldn’t be seen before
- Study Suggests New Criteria For Electrocatalysts
- Theoretical findings on O2 reduction energetics should help the selection of better-performing fuel-cell catalysts
- Rhodium-Catalyzed Reaction Pinned Down
- Calculations suggest the C–H activation/Cope rearrangement combo can be customized to deliver multiple chiral products
- Mycobacteria Have A System For Acquiring Iron From Heme
- In addition to using iron-chelating siderophores, the tuberculosis microbe uses a heme-binding protein to grab iron
- … And Can Now Enter The Spotlight For In-Cell Detection
- Scientists unveil the first molecular probe for live, in-cell detection of the pathogenic bacterium
- Nanotube Confinement Boosts Catalysis
- Platinum nanoparticles inside carbon nanotubes are effective catalysts for asymmetric hydrogenations
- Laser-Induced Shock Wave Chromatography
- Proteins and quantum dots can be separated for analysis by the impact induced by a laser shock wave
- Forster Reaction Delivers Generic Drug
- A novel synthetic route to make a hyperparathyroidism drug uses a century-old, unexplored method
Topics Covered
Through theoretical and experimental studies, chemists have learned how a catalytic asymmetric reaction called the combined C–H activation/Cope rearrangement works (J. Am. Chem. Soc., DOI: 10.1021/ja111408v). The reaction (shown) is generally selective for one stereochemical outcome, but the new work suggests it’s possible to obtain several products at will. The rhodium-mediated reaction is “a powerful transformation that has been used effectively in complex molecule assembly,” says organic chemist Joseph M. Fox of the University of Delaware. However, the mechanism for the process wasn’t clear before now. Emory University’s Jørn H. Hansen and Huw M. L. Davies, director of the NSF Center for Stereoselective C–H Functionalization, and colleagues determined that the transformation proceeds through a hydride transfer and carbon-carbon bond formation. Energy differences between the reaction’s possible transition states are small, which indicates that different chiral products should be obtainable in a controlled manner with modified reagents, something Davies’ lab has accomplished but not yet reported. This study “places the reaction on sound mechanistic footing and provides chemists with a predictive computational tool for understanding chemoselectivity and regioselectivity,” Fox says.
- Chemical & Engineering News
- ISSN 0009-2347
- Copyright © 2011 American Chemical Society
Services & Tools
ACS Resources
ACS Careers
ACS is the leading employment source for recruiting scientific professionals. ACS Careers and C&EN Classifieds provide employers direct access to scientific talent both in print and online. Jobseekers | Employers
» Join ACS
Join more than 161,000 professionals in the chemical sciences world-wide, as a member of the American Chemical Society.
» Join Now!
Popular Sections
ACS, Analytical SCENE, Business, Careers, Economy, Editor, Education, Employment, Environmental SCENE, Letters, Government, Photo Galleries, Policy, Movies, Multimedia, Nanotechnology, Newscripts, Reel Science, Safety Letters, Science, Stem Cells, Stimulus Funds, Technology, Vaccines, Videos, What's That Stuff
Advertisements
