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
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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.
Measuring interaction between particles in condensed matter has been of paramount interest since it provides a starting point for describing the statistical properties of the system under consideration.
This measurement is correlated directly to ultrahigh energy-resolution monochromated electron energy-loss spectroscopy (EELS) measurements, which are able to directly measure the phonon response at the nano-length-scales of the long and short-period sup
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.
Using first-principles calculations and group-theory-based models, we study the stabilization of ferrielectricity (FiE) in CuInP2Se6.
Using ab initio tight-binding approaches, we investigate Floquet band engineering of the 1T' phase of transition metal dichalcogenides (MX2, M = W, Mo and X = Te, Se, S) monolayers under the irradiation with circularly