Projects - CMIT

Integrated 2D Semiconductors for Quantum Optomechanical Sensing (i2D)

This project develops ultrathin, ultrasensitive optomechanical sensors for medical and defence applications by integrating Silicon Carbide nanofilms with atomically thin 2D materials and controlling charge-carrier quantum dynamics at heterojunctions. The approach overcomes rigidity and sensitivity limits of current solid-state sensors, enabling advances in ultrasensitive sensing and wearable miniaturisation. The outcomes will strengthen Vietnam’s semiconductor workforce and technical capacity, delivering significant social and economic benefits.

In-situ optical monitoring of monolayer MoS2 via micro-CVD and its application in optoelectronic devices and stabilized high-efficiency perovskite solar cells

Two-dimensional semiconductors like monolayer MoS₂ are crucial for next-generation sensing, computing, and energy technologies, but reproducible synthesis remains a major obstacle. This project uses a micro-CVD system with real-time optical monitoring to visualize growth processes and establish reliable monolayer formation. The resulting high-quality MoS₂ will be integrated into perovskite solar cells and devices such as photodetectors and FETs.

Theory-Guided Design of Spintronic Materials using Advanced Multiscale Analysis

Principal Investigators & Key Members:

Nguyen Tuan Dung, PhD

This project develops advanced 2D magnetic and spin-active materials for next-generation spintronic technologies, including sensors, nonvolatile memory, and energy-efficient logic. By integrating material synthesis, device fabrication, magnetotransport measurements, and computer simulations, the research will study and optimize spin-dependent interactions. The goal is to deliver high-quality materials and device designs with faster, more efficient, and more reliable spintronic performance.