Ultraflexible Wireless Imager Integrated with Organic Circuits for Broadband Infrared Thermal Analysis.
Rei KawabataKou LiTeppei ArakiMihoko AkiyamaKaho SugimachiNozomi MatsuokaNorika TakahashiDaiki SakaiYuto MatsuzakiRyo KoshimizuMinami YamamotoLeo TakaiRyoga OdawaraTakaaki AbeShintaro IzumiNaoko KurihiraTakafumi UemuraYukio KawanoTsuyoshi SekitaniPublished in: Advanced materials (Deerfield Beach, Fla.) (2024)
Flexible imagers are currently under intensive development as versatile optical sensor arrays, designed to capture images of surfaces and internals, irrespective of their shape. A significant challenge in developing flexible imagers is extending their detection capabilities to encompass a broad spectrum of infrared light, particularly terahertz (THz) light at room temperature. This advancement is crucial for thermal and biochemical applications. In this study, a flexible infrared imager is designed using uncooled carbon nanotube (CNT) sensors and organic circuits. The CNT sensors, fabricated on ultrathin 2.4 µm substrates, demonstrate enhanced sensitivity across a wide infrared range, spanning from near-infrared to THz wavelengths. Moreover, they retain their characteristics under bending and crumpling. The design incorporates light-shielded organic transistors and circuits, functioning reliably under light irradiation, and amplifies THz detection signals by a factor of 10. The integration of both CNT sensors and shielded organic transistors into an 8 × 8 active-sensor matrix within the imager enables sequential infrared imaging and nondestructive assessment for heat sources and in-liquid chemicals through wireless communication systems. The proposed imager, offering unique functionality, shows promise for applications in biochemical analysis and soft robotics.