MIT

MIT and Graphenea have developed an array of graphene sensors for sensitive and selective detection of ammonia. The array consists of 160 graphene pixels, allowing large statistics that result in improved sensing performance. The sensors are extensively tested for various real-life operational conditions, which seems to be a step forward to practical use.

The sensors are built by attaching porphyrins, a class of organic molecules, to the graphene surface. Porphyrins are particularly well-matched to graphene sensors because they provide excellent sensitivity while producing minimal perturbation to graphene’s outstanding electrical properties. When ammonia molecules attach to porphyrins, the compound becomes a strong dipole that changes electrical properties of the graphene. This electrical change is detected as a sign of the presence of ammonia.

A team of researchers at MIT, Raytheon BBN Technologies and Columbia University have used graphene to design a fast yet highly sensitive bolometer that can work at room temperature and may even be less expensive. Bolometers are devices that monitor electromagnetic radiation through heating of an absorbing material. Most such devices have limited bandwidth and must be operated at ultralow temperatures, which damages their usefulness.

The findings of this work could help pave the way toward new kinds of astronomical observatories for long-wavelength emissions, new heat sensors for buildings, and even new kinds of quantum sensing and information processing devices, the multidisciplinary research team says.