TY - JOUR
T1 - Beyond Flexible
T2 - Unveiling the Next Era of Flexible Electronic Systems
AU - Kim, Min Sung
AU - Almuslem, Amani S.
AU - Babatain, Wedyan
AU - Bahabry, Rabab R.
AU - Das, Uttam K.
AU - El-Atab, Nazek
AU - Ghoneim, Mohamed
AU - Hussain, Aftab M.
AU - Kutbee, Arwa T.
AU - Nassar, Joanna
AU - Qaiser, Nadeem
AU - Rojas, Jhonathan P.
AU - Shaikh, Sohail F.
AU - Torres Sevilla, Galo A.
AU - Hussain, Muhammad M.
N1 - Publisher Copyright:
© 2024 The Author(s). Advanced Materials published by Wiley-VCH GmbH.
PY - 2024
Y1 - 2024
N2 - Flexible electronics are integral in numerous domains such as wearables, healthcare, physiological monitoring, human–machine interface, and environmental sensing, owing to their inherent flexibility, stretchability, lightweight construction, and low profile. These systems seamlessly conform to curvilinear surfaces, including skin, organs, plants, robots, and marine species, facilitating optimal contact. This capability enables flexible electronic systems to enhance or even supplant the utilization of cumbersome instrumentation across a broad range of monitoring and actuation tasks. Consequently, significant progress has been realized in the development of flexible electronic systems. This study begins by examining the key components of standalone flexible electronic systems–sensors, front-end circuitry, data management, power management and actuators. The next section explores different integration strategies for flexible electronic systems as well as their recent advancements. Flexible hybrid electronics, which is currently the most widely used strategy, is first reviewed to assess their characteristics and applications. Subsequently, transformational electronics, which achieves compact and high-density system integration by leveraging heterogeneous integration of bare-die components, is highlighted as the next era of flexible electronic systems. Finally, the study concludes by suggesting future research directions and outlining critical considerations and challenges for developing and miniaturizing fully integrated standalone flexible electronic systems.
AB - Flexible electronics are integral in numerous domains such as wearables, healthcare, physiological monitoring, human–machine interface, and environmental sensing, owing to their inherent flexibility, stretchability, lightweight construction, and low profile. These systems seamlessly conform to curvilinear surfaces, including skin, organs, plants, robots, and marine species, facilitating optimal contact. This capability enables flexible electronic systems to enhance or even supplant the utilization of cumbersome instrumentation across a broad range of monitoring and actuation tasks. Consequently, significant progress has been realized in the development of flexible electronic systems. This study begins by examining the key components of standalone flexible electronic systems–sensors, front-end circuitry, data management, power management and actuators. The next section explores different integration strategies for flexible electronic systems as well as their recent advancements. Flexible hybrid electronics, which is currently the most widely used strategy, is first reviewed to assess their characteristics and applications. Subsequently, transformational electronics, which achieves compact and high-density system integration by leveraging heterogeneous integration of bare-die components, is highlighted as the next era of flexible electronic systems. Finally, the study concludes by suggesting future research directions and outlining critical considerations and challenges for developing and miniaturizing fully integrated standalone flexible electronic systems.
KW - CMOS technology
KW - flexible electronics
KW - transformational electronics
UR - http://www.scopus.com/inward/record.url?scp=85205950375&partnerID=8YFLogxK
U2 - 10.1002/adma.202406424
DO - 10.1002/adma.202406424
M3 - Review article
AN - SCOPUS:85205950375
SN - 0935-9648
JO - Advanced Materials
JF - Advanced Materials
ER -