A subtle twist between atomically thin magnetic layers can generate unexpectedly large and complex spin structures.

With a new mathematical model, a team of biophysicists has revealed fresh insights into how biological tissues are shaped by the active motion of structural imperfections known as "topological defects ...

Researchers show a temperature tunable smart fluid that overcomes limits in liquid crystal microcolloids, enabling ...

Studying twisted double-bilayer chromium triiodide (CrI₃) with scanning nitrogen–vacancy magnetometry, the authors directly image magnetic fields with nanoscale resolution and observe long-range ...

In the rapidly evolving world of two-dimensional materials, a small twist can have outsized consequences. Since the discovery that rotational ...

Seoul National University College of Engineering announced that a research team led by Prof. Sunkyu Yu and Prof. Namkyoo Park ...

In the rapidly evolving world of two-dimensional materials, a small twist can have outsized consequences. Since the discovery that rotational misalignment between atomically thin crystals can reshape ...

A novel type of three-dimensional (3D) polar topological structure, termed the "polar chiral bobber," has been discovered in ferroelectric oxide thin films, demonstrating promising potential for ...

Abstract: Topological edge states have gained significant attention due to their exceptional capability to transmit signals without being affected by defects, which make them promising for ...

Abstract: Neural architecture search (NAS) is crucial for text representation in natural language processing (NLP); however, much less work on NAS for text classification has been proposed compared ...