CMOS-Compatible Strain Engineering in Monolayer Semiconductor Transistors Academic Background With the continuous advancement of semiconductor technology, two-dimensional (2D) materials have garnered significant attention for their atomic-level thinness, which makes them ideal for high-density, low-power electronic devices. Among them, transition m...

Report on the Academic Paper Inflammatory skin diseases, such as psoriasis and rosacea, are common chronic skin conditions worldwide, significantly impacting patients’ quality of life. Traditional topical drug delivery methods, while simple and non-invasive, suffer from poor skin penetration and long-term side effects. Therefore, developing an effe...

Dynamic 3D Metasurface Holography via Cascaded Polymer Dispersed Liquid Crystal Academic Background Metasurfaces, as two-dimensional subwavelength structures, enable local modulation of the phase and amplitude of light fields, offering novel solutions for the design of miniaturized optical devices. However, most existing metasurface holographic dis...

Root-Inspired, Template-Constrained Additive Printing for Fabricating Highly Robust Conformal Electronics Academic Background With the rapid development of emerging application scenarios such as smart robotics, smart skins, and integrated sensing systems, the application of conformal electronic devices on freeform surfaces has become crucial. Howev...

Study of Nonlinear Coupling in Atomically Thin MoS₂ Nanoelectromechanical Resonators Academic Background With the rapid development of nanotechnology, Nanoelectromechanical Systems (NEMS) have shown great potential in fields such as sensors, signal processing, and quantum computing. Particularly, two-dimensional (2D) materials like molybdenum disul...

Advancement in Piezoelectric Nanogenerators for Acoustic Energy Harvesting Academic Background With the proliferation of Internet of Things (IoT) devices, the demand for sustainable energy sources has been increasing. Traditional battery-powered systems face limitations such as finite lifespan and high maintenance costs, prompting researchers to ex...

Academic Background Protein self-assembly is a ubiquitous phenomenon in biological systems, performing a wide range of functions from structural support to biochemical regulation. Despite significant progress in protein design in recent years, existing self-assembling protein structures typically rely on strict symmetry, which limits their size and...

Design of Four-Component Protein Nanocages through Programmed Symmetry Breaking Academic Background Protein nanocages are highly symmetric protein assemblies widely used in vaccine development, drug delivery, and nanomaterial design. In nature, viruses often construct complex structures through symmetry breaking, particularly in high triangulation ...

Research on Growth-Based Monolithic 3D Integration of Single-Crystal 2D Semiconductors Academic Background With the rapid development of the modern electronics industry, three-dimensional (3D) integration technology has gradually become an important means to enhance the performance of electronic devices. Traditional two-dimensional (2D) integrated ...

MINFLUX Nanoscopy in Biological Tissue: Breaking the Resolution Barrier of Fluorescence Microscopy Academic Background Fluorescence microscopy plays a crucial role in biological research, but its resolution is limited by the diffraction barrier, typically around 200 nanometers. In recent years, the development of super-resolution microscopy (SR) te...