From predicting molecular behavior to generating practice problems, AI is transforming how chemists and students approach complex challenges. Quantum computing models, machine learning fingerprints, ...

Scientists and researchers have long extolled the extraordinary potential capabilities of universal quantum computers, like simulating physical and natural processes or breaking cryptographic codes in ...

A gold superconducting quantum computer hangs against a black background. Quantum computers, like the one shown here, could someday allow chemists to solve problems that classical computers can’t.

Gas stoichiometry becomes more approachable when learners connect core concepts with guided problem-solving techniques. By combining the ideal gas law with balanced equations, they can predict gas ...

Unfortunately, this book can't be printed from the OpenBook. If you need to print pages from this book, we recommend downloading it as a PDF. Visit NAP.edu/10766 to get more information about this ...

Computing hasn’t changed fundamentally since the advent of the abacus 4,500 years ago. But that could change imminently as the world ushers in the quantum computer, a radically new type of computing ...

This chapter highlights some of the most prominent research challenges from theoretical/computational chemistry that appear to be amenable to attack with the help of ...

A chemist’s impact extends far beyond the lab. With an advanced degree in chemistry, you’ll be a problem-solver. You’ll make a meaningful impact on people and places around the world by ...