We demonstrated how Rayleigh’s law for phonon scattering can be broken by spatially correlated point defects resulting in an order of magnitude reduction of thermal conductivity.
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Existing material synthesis and device fabrication methods do not provide the required precision to create and position quantum-active defects.
The interplay between topology and magnetism can lead to many exotic states.
Vortices in unconventional superconductors can support fundamentally new electronic excitations and act as a basic building block of quantum computing architecture.
A real-time feedback approach was used to reveal and control the transformational pathways during the top-down synthesis of Janus WSSe monolayers and its fractional alloys with pulsed laser deposition.
Competition among exchange interactions is able to induce novel spin correlations on a bipartite lattice without geometrical frustration.
The electronic instabilities in CsV3Sb5 are believed to originate from the V 3d-electrons on the kagome plane, however the role of Sb 5p-electrons for 3-dimensional orders is largely unexplored.
– Materials in which you can manipulate the proportion of oxide ions are considered good candidates for the development of devices that employ ionotronics (powerful tools and methods for narrowing the gap between conventional electronics and biological
Understanding the effects of electronic frustration on the kagome lattice is a very active area in correlated materials physics.