Scientists have discovered that integrin proteins adopt different shapes that determine their cellular journey. The inactive form travels to the Golgi apparatus via galectin-3, while active forms take different routes. This finding could revolutionize targeted drug delivery approaches.
A breakthrough manufacturing approach has enabled the creation of non-van der Waals superlattices from transition metal carbides and carbonitrides. These novel structures feature hydrogen bonding between layers, offering enhanced electronic coupling compared to traditional materials.
Researchers have developed an innovative method for creating non-van der Waals superlattices using transition metal carbides and carbonitrides, according to recent reports in Nature. This advancement represents a significant departure from conventional superlattice construction, which typically relies on van der Waals materials with weak interlayer interactions. The new approach enables stronger interface coupling through hydrogen bonding, potentially opening doors to enhanced electronic and magnetic properties for next-generation devices.
The Geometry Problem in Microscale Physics Recent experimental work with micrometre-scale re-entrant cavities has revealed a significant discrepancy between measured…
Researchers have demonstrated ultrastrong light-matter interactions in van der Waals heterostructures, according to a Nature Physics study. The findings reveal how built-in plasmonic cavities in graphite gates can control quantum phenomena in these layered materials, opening new pathways for quantum material engineering.
Scientists have achieved a significant advancement in controlling quantum phenomena through built-in light cavities in van der Waals heterostructures, according to reports published in Nature Physics. Researchers have observed ultrastrong coupling between graphene and graphite plasmonic modes, demonstrating how intrinsic cavity effects can shape the electrodynamics of these layered materials. The findings reportedly provide new pathways for engineering quantum phases and developing novel functionality in two-dimensional material systems.
