Using a rapid pressure-quench technique, researchers have preserved a metastable phase in a superconductor at a record 151 K under ambient pressure.

Multiferroic metals are materials that exhibit both electric polarization and magnetic order in the same crystal—a state known as multiferroicity. Because these properties coexist, they can interact through magnetoelectric (ME) coupling, allowing electric fields to influence magnetism.

Unfortunately, bulk multiferroic materials face limitations, including relatively small spontaneous polarization, weak ME coupling coefficients, and limited operational stability under ambient conditions due to oxygen-vacancy-induced leakage currents, which restrict their practical applications.

Now, however, researchers from the Institute of Physics of the Chinese Academy of Sciences, along with their collaborators from Zhejiang University, have realized electric-field control of magnetic states using a two-dimensional (2D) van der Waals material, while demonstrating intrinsic room-temperature (RT) multiferroicity with strong ME coupling.

Planting vacancies into the atomic lattice of a brittle material increases its toughness and hardness.

A newly mapped form of superconductivity in uranium ditelluride emerges only under extremely strong magnetic fields, defying long-held expectations about how superconductors behave.

Chiral amines are privileged chiral building blocks with extensive applications in pharmaceuticals, advanced materials, and asymmetric catalysis owing to their unique structural features and functional diversity. Although palladium-catalyzed asymmetric allylic C–H amination offers an efficient strategy for constructing these motifs, the simultaneous challenges of coordinating sterically hindered internal alkenes and suppressing catalyst deactivation by Lewis basic amines have severely limited the development of asymmetric oxidative amination systems. In this study, we disclose a novel ester, an unmodified native functional group-directed strategy that enables the palladium-catalyzed asymmetric oxidative allylic amination of internal α,β-unsaturated esters with basic amines. This protocol yields a diverse array of non-natural γ-amino acid derivatives with excellent yields and high enantioselectivity (93% to >99% e.e.). Comprehensive mechanistic investigations, incorporating controlled experiments and density functional theory calculations, elucidate the intricate reaction pathway. The synthetic utility is further demonstrated through various product derivatizations and the streamlined synthesis of bioactive compounds. This work establishes a general platform for accessing enantioenriched nitrogen-containing architectures from readily available alkenes and amines.