Engineers at MIT have developed a new way to make extremely thin, flexible layers of electronic material—what they call.” ...

Explore how MIT’s ultrathin electronic films revolutionise thermal sensing and imaging devices. Read the full article.

Engineers have developed a technique to grow and peel ultrathin “skins” of electronic material. The method could pave the way ...

Filling this gap, researchers at the Peking University School of Electronics and collaborators ... indicates that the HGFET can detect weak infrared radiation at 0.46 nW cm −2 levels, thus ...

Detecting infrared radiation. Everything above absolute zero emits infrared radiation, which is also perceived as heat in the far infrared (FIR) range. In normal environments, people and animals ...

MIT engineers have developed an incredibly thin and flexible material that could lead to lightweight, wearable night-vision ...

The thin film senses heat without cooling systems. It could lead to smaller night-vision glasses and better sensors for uses ...

It’s called absolute zero. Any object with a temperature above this will emit and absorb infrared radiation, even the Earth. Speaker two That’s right, and the rate at which infrared radiation ...

Technology has now moved on, and it is now possible to generate continuous-wave terahertz radiation by exposing a semiconductor to beams from two infrared laser diodes that are very close in ...

An electronic sensor "skin" grown by MIT engineers could revolutionize next-generation night vision and autonomous vehicles.

It’s called absolute zero. Any object with a temperature above this will emit and absorb infrared radiation, even the Earth. Speaker two That’s right, and the rate at which infrared radiation ...

The method could pave the way for new classes of electronic devices ... that the film is highly sensitive to heat and radiation across the far-infrared spectrum. The newly developed film could ...