Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain
the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in
Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles
and JavaScript.
Long ago, a global search for borane superfuels led fortuitously to the discovery of carboranes. Ken Wade recalls his own undistinguished part in the space race, and notes how carboranes revitalized boron hydride chemistry and modified our ideas of chemical bonding.
The continued rise of the internet and so-called 'Web 2.0' developments in particular, offer new opportunities for how chemical information can be stored and shared online — and could transform how the subject is taught and reported.
With energy swiftly rising to the top of the world's agenda, Harry B. Gray at the California Institute of Technology looks at how chemistry can help to harness the power of the Sun to meet the world's energy needs.
Chemistry has a central role in science, and synthesis has a central role in chemistry. Ryoji Noyori from Nagoya University considers where synthetic chemists should focus their efforts.
Mark A. Johnson at Yale University discusses how the two sides of physical chemistry have necessarily developed together, and looks at how their synergy dictates the direction of contemporary research.
The foundations of science are built on the ability to make sensitive, precise measurements. Gary M. Hieftje from Indiana University, Bloomington, considers how analytical instruments and methods are being developed to meet tomorrow's needs.
If syntheses and structures can be more easily predicted, what will it mean for inorganic chemistry? Achim Müller of the University of Bielefeld looks into his (quasi)crystal ball.
Online courses administered by the University of Illinois at Urbana-Champaign show that it is possible to create an effective network of professors and students from across institutional and national borders all learning together — even in conceptually challenging subjects such as organic chemistry.
The way forward for a field in its infancy is to focus on complexity and integrated systems that may lead to emergent phenomena, suggests J. Fraser Stoddart at Northwestern University.
Understanding the mysteries of life has always been a driving force in scientific research; Barbara Imperiali from the Massachusetts Institute of Technology reflects on the infinite opportunities for chemists at the biology interface.
Diminishing fossil fuel reserves, hazardous chemicals and wasteful processes have led to the emergence of 'green' technologies; James H. Clark at the University of York considers how metals, materials and organic compounds can be prepared by clean and sustainable routes.
The closest that most chemists get to the concepts of nonlinearity and emergent properties is a passing acquaintance with a well-known oscillating reaction. Bruce C. Gibb suggests that looking a little deeper into chaos and complexity could help us to answer some very important questions.