The Micro-Nano Chip Industrialization Center faces the forefront of disciplines, is guided by the strategic needs of major national projects and regional economic development needs, combines modern physical principles and advanced engineering technology, optimizes interdisciplinary disciplines, builds an innovative and compound talent training base, and creates an internationally advanced Even leading innovative technologies serve the Guangdong-Hong Kong-Macao Greater Bay Area and promote the country's industrial upgrading. The Micro-Nano Chip Industrialization Center has a MEMS chip and device laboratory, an optoelectronic chip and device laboratory, a chip and device packaging laboratory, a simulation laboratory, etc. It has a team of disciplines with backgrounds covering MEMS , optoelectronics, optical engineering, laser, High-level teaching and research teams in applied physics, materials physics, computing science and other fields.

The Hall magnetic sensor is a magnetic field sensor based on the Hall effect. It detects physical quantities such as linear displacement, angular displacement, speed and direction, pressure, torque, and position by detecting changes in the external magnetic field. Integrated Hall sensors use silicon integrated circuit technology to integrate Hall components and measurement circuits, realizing the trinity of materials, components, and circuits. Hall sensors are mainly divided into two categories: switching Hall sensors and linear Hall sensors, which are widely used in industry, consumer electronics, home appliances, automobiles, heavy machinery and other fields.

Ion trap qubit chip: Any system with two possible quantum states, such as the ground state and excited state of trapped ions, can constitute a qubit. The technical principle of ion trap qubits is to use the interaction force between charges and electromagnetic fields to contain the movement of charged ions, and use the two energy levels composed of the ground state and excited state of the trapped ions as qubits. The qubits are driven by laser and The coupling of joint vibration modes of ion chains realizes the entanglement between bits. By trapping multiple ions in a single potential well, the number of qubits can be expanded to tens to hundreds. Ion trap qubits have the longest qubit coherence time, can perform high-fidelity quantum state measurements and quantum gate operations, and can realize programmable quantum computers based on this.