Variations in the vibrations of beams of silicon create a sensitive way of measuring pressure changes

A micrometer-scale, low-power consumption pressure sensor has been developed by KAUST scientists, with potential applications in vacuum environments.

Sensors are the interface between automated systems, such as computers and robots, and their environment. Sensors measure light, temperature, motion, mass, pressure, position and much more. The push is to make sensors smaller, so that they can be integrated into portable products. Pressure sensors, for example, are used in industrial control, healthcare, medical testing and meteorology. Depending on the application, these sensors need to be sensitive to small changes, quick to respond to these changes, and work over a wide range of pressures.

Nouha Alcheikh, Amal Hajjaj and Mohammad Younis have now developed a sensitive pressure microsensor based on a vibrating beam of silicon just 800 micrometers long, 25 micrometers wide and 1.5 micrometers thick. "We have developed a scalable and sensitive micropressure sensor that operates over an extended range of pressures in the nanoregime," says Alcheikh.

A suspended beam will oscillate at a resonant frequency that is determined by its mass, length, density and stiffness. As a current is passed through the beam, it gets hotter and begins to bend. This increased curvature increases the stiffness of the beam and thus moves the resonant frequency. Air surrounding the beam cools it down: the higher the pressure, the more air, the better the cooling. Thus, the resonant frequency of the beam, which can be measured electrically, is related to the pressure.

The device the team created operates over a wide range of pressures, from 0.038 Torr to 200 Torr (atmospheric pressure is 760 Torr). The sensor has a sensitivity of 2689 x 10^-6 / Torr.

The team also showed that the sensor can be tailored for a specific application by changing the beam's thickness. They simulated the operation of the beam to demonstrate that the sensitivity becomes higher for a thinner microbeam, but a thicker beam consumes more energy. Thus, an optimum thickness could be calculated for the best sensitivity at low or high pressures, depending on the target environment for the device.

"We are lucky to have the ability to explore wild and new ideas, such as this novel pressure sensor, thanks to the state-of-art facilities at KAUST," says Younis. "I hope to continue making use of this opportunity to take this device concept into commercialization."