Quantum control encompasses the advanced techniques employed to manipulate and steer quantum systems towards desired outcomes. Within this field, adiabatic processes have long served as a robust ...

Researchers have made a meaningful advance in the simulation of molecular electron transfer -- a fundamental process underpinning countless physical, chemical and biological processes. The study ...

Researchers used atomic clock laser methods and a helper calcium atom to control a calcium monohydride molecule, expanding ...

A team of Johns Hopkins engineers has developed a new, more powerful method to observe molecular vibrations, an advance that could have far-reaching implications for early disease detection. The team, ...

Scientists were able to manipulate a calcium monohydride molecular ion — made up of one atom of hydrogen and one atom of ...

Quantum effects are no longer confined to ultra-cold chips and vacuum chambers. For the first time, researchers have ...

Researchers at Google Quantum AI have used their Willow quantum computer to help interpret data from Nuclear Magnetic Resonance (NMR) spectroscopy, a mainstay of chemistry and biology research. The ...

Scientists at the University of Chicago and partner institutions have demonstrated a new type of molecular qubit that operates at standard telecommunications wavelengths. The breakthrough could enable ...

Scientists at the University of Chicago and partner institutions have developed molecular qubits compatible with standard telecommunications networks—a key step toward a future “quantum internet.” The ...

Quantum light sources often produce inconsistent or contaminated single photons, limiting the reliability of quantum technologies. Researchers coated atomically thin tungsten diselenide with a uniform ...