Recently, the MEMS team at the School of Mechanical Engineering, Sichuan University, made significant progress in the field of flexible wearable sensor devices. They proposed a strain sensor based on a synergistic ionic-electronic transport channel mechanism, which effectively resolves the trade-off between sensitivity and sensing range by leveraging impedance mismatch between the electronic sensing layer and the ionic sensing layer, along with a unique sensing mechanism.

In the current era of rapid development in the semiconductor industry, chip manufacturing processes continue to advance toward nanometer and even sub-nanometer levels. The precision and operational stability of semiconductor equipment directly determine product quality and production efficiency. As the "intelligent eyes" of the semiconductor equipment monitoring system, sensors play a crucial role in ensuring the safe and efficient operation of semiconductor production processes, leveraging their core capabilities of precise sensing and real-time feedback.

Recently, the team led by Huo Yixin from the School of Life Sciences at Beijing Institute of Technology published a research article titled "Design of Strictly Orthogonal Biosensors for Maximizing Renewable Biofuel Overproduction" in the top tier journal "Journal of Advanced Research" in Zone 1. This study developed a machine learning based design method to address the relationship between signal molecule promiscuity and industrial orthogonality.

Recently, the distributed single-fiber multi-parameter monitoring and sensing system developed by Professor Dong Yongkang's team from the School of Aerospace Engineering at Harbin Institute of Technology has been successfully applied to the monitoring and early warning of threat events in actual long-distance oil and gas pipelines. The review committee organized by the National Pipeline Network Group unanimously concluded that this achievement meets the requirements for on-site application.

Recently, a research article titled "Design of Strictly Orthogonal Biosensors for Maximizing Renewable Biofuel Overproduction" by the team of Professor Huo Yixin from the School of Life Sciences at Beijing Institute of Technology was published in the top-tier journal "Journal of Advanced Research" (Zone 1).

In the field of sensor testing and measurement, the prerequisite for accurately capturing signals is to create an "interference-free" environment. Vibration and noise reduction equipment must not only mitigate the interference from vibrations and noise but also eliminate its own impact on the testing system through "stealth design." This "stealth feature" has become the core competitiveness of high-end testing equipment.