Various materials can be converted into carbon in order to generate graphene through laser radiation. Known as laser-induced graphene (LIG), the material formed can contain specific properties that are determined by the original material.<\/p>\n

The researchers decided to experiment with this process. Samples of polyimide, a type of plastic, were irradiated through laser scanning. The team varied the power, scanning speed, number of passes and density of scanning lines.<\/p>\n

\u201cWe wanted to look at how different parameters of the laser processing process create different nanostructures,\u201d Cheng said. \u201cVarying the power allowed us to create LIG either in a fibre or foam structure.\u201d<\/p>\n

The team discovered that lower power levels, between approximately 7.2 watts and nine watts, led to the development of a porous foam with many ultrafine layers. This laser-induced graphene foam displayed electrical conductivity and a reasonable resistance to heat damage, both of which are useful properties for components of electronic devices.<\/p>\n

By raising the power from around nine watts to 12.6 watts, the researchers found that this shifted the LIG formation pattern from foam to bundles of small fibres. These bundles grew bigger in diameter with increased laser power, while higher power promoted the web-like growth of a fibre network. The fibrous structure revealed better electrical conductivity than the foam. According to Cheng, this enhanced performance combined with the fibre\u2019s form may open possibilities for sensing devices.<\/p>\n

\u201cIn general, this is a conductive framework we can use to construct other components,\u201d Cheng explained. \u201cAs long as the fibre is conductive, we can use it as a scaffold and do a lot of subsequent modifications on the surface to enable a number of sensors, such as a glucose sensor on the skin or an infection detector for wounds.\u201d<\/p>\n

By adjusting the laser scanning speed, density and passes for the laser-induced graphene formed at different powers, the conductivity and subsequent performance were also influenced. More laser exposure led to greater conductivity, but ultimately fell as a result of excess carbonisation from burning.<\/p>\n

Utilising their first study as a foundation, the researchers designed, fabricated and tested a flexible LIG pressor sensor.<\/p>\n

\u201cPressure sensors are very important,\u201d Cheng said. \u201cWe can use them not only in households and manufacturing but also on the skin surface to measure lots of signals from the human body, like the pulse. They can also be used at the human-machine interface to enhance performance of prosthetic limbs or monitor their attachment points.\u201d<\/p>\n

The researchers experimented with two different designs. To begin, they sandwiched a thin laser-induced graphene foam layer between two polyimide layers comprising copper electrodes. When pressure was applied, the LIG generated electricity.<\/p>\n

The voids in the foam decreased the number of pathways for electricity to travel, making it easier to localise the pressure source, and seemed to enhance sensitivity to delicate touches.<\/p>\n

When attached to the back of the hand or the finger, this design was able to identify bending and stretching hand movements, on top of the characteristic percussion, tidal and diastolic waves of the heartbeat. According to Cheng, it is possible to combine this pulse reading with an electrocardiogram reading to produce blood pressure measurements without a cuff.<\/p>\n