Spiral spin-liquids are correlated paramagnetic states with degenerate propagation vectors forming a continuous ring or surface in reciprocal space.
Researchers discovered a mechanism for creating novel electronic materials by reversible phase transformations of the perovskite oxygen sublattice.1 The reversible tuning of the oxygen sublattice greatly expands the parameter space of magnetic and elect
Metallic glasses are promising as structural materials because of high mechanical strength, but they often lack ductility, limiting their application. However, the origin of the low ductility is not well-understood.
Manipulating the type and degree of spin and exchange disorder in a crystal lattice provides new design principles to create highly tunable magnetic order.
Practical applications of the real-space diffusion Monte Carlo (DMC) method require the removal of core electrons, where currently localization approximations of semilocal potentials are generally used in the projector.
High entropy ceramics provide enhanced flexibility for tailoring a wide range of physical properties, emerging from the diverse chemical and configurational degrees of freedom.
Neutron scattering reveals easy and complete switching between planar and axial spins upon doping with Li in antiferromagnetic MnTe. Easy control of the spin orientation is a crucial step towards increasing functionalities and developing easy
Large-scale numerical calculations reveal fluctuating spin and charge stripes intertwined with pair-density-wave
