New materials can turn clothing into health monitors, The researchers report a new material that is flexible enough to be woven into fabric, but infused with sensory abilities that can function as an early warning system for injury or disease.

The material uses carbon nanotubes and can detect slight changes in body temperature while maintaining a flexible and destroyed structure as opposed to a solid crystal structure. This makes it a good candidate for wear or temperature sensor wear. human body.

Changes in body heat change electrical resistance and warn someone that it is changing so that it requires the possibility of interference.

Your body can tell you that something is wrong before it becomes clear.

Possible applications range from detection of dehydration in ultramarathon runners to the onset of tenderness in nursing home patients.

The researchers say it is also inexpensive because the raw materials needed are used in relatively low concentrations.

Materials made using graphs of poly (octadecyl acrylate) multinuclear carbon nanotubes are technically known as nanocarbons, which are based on conductive polymer nanocomposites, or DCPN, a class of materials that is increasingly used in materials science. New materials can turn clothing into health monitors.

However, most DCPN materials are poor conductors, making them unsuitable for use in portable technology where they need to detect small changes in temperature.

The new material is made using a technique called RAFT polymerization, said Wang, a critical step that will allow polymers to be electronically and phonically bound to multinuclear carbon nanotubes with covalent bonds. New materials can turn clothing into health monitors.

Therefore, the fine structure diagram is electronically amplified with respect to the glass transition temperature of the system to obtain the very large electronic response given in the article without the negatives associated with solid phase transitions.

Subtle structural changes related to the glass transition process are usually too small to produce a sufficiently large electronic response.