TY - JOUR
T1 - Flexible Electronics: Status, Challenges and Opportunities
AU - Corzo Diaz, Daniel Alejandro
AU - Tostado Blazquez, Guillermo
AU - Baran, Derya
N1 - KAUST Repository Item: Exported on 2021-02-23
PY - 2020/9/30
Y1 - 2020/9/30
N2 - The concept of flexible electronics has been around for several decades. In principle, anything thin or very long can become flexible. While cables and wiring are the prime example for flexibility, it was not until the space race that silicon wafers used for solar cells in satellites were thinned to increase their power per weight ratio, thus allowing a certain degree of warping. This concept permitted the first flexible solar cells in the 1960s (Crabb and Treble, 1967). The development of conductive polymers (Shirakawa et al., 1977), organic semiconductors, and amorphous silicon (Chittick et al., 1969; Okaniwa et al., 1983) in the following decades meant huge strides toward flexibility and processability, and thus these materials became the base for electronic devices in applications that require bending, rolling, folding, and stretching, among other properties that cannot be fulfilled by conventional electronics (Cheng and Wagner, 2009) (Figure 1).
AB - The concept of flexible electronics has been around for several decades. In principle, anything thin or very long can become flexible. While cables and wiring are the prime example for flexibility, it was not until the space race that silicon wafers used for solar cells in satellites were thinned to increase their power per weight ratio, thus allowing a certain degree of warping. This concept permitted the first flexible solar cells in the 1960s (Crabb and Treble, 1967). The development of conductive polymers (Shirakawa et al., 1977), organic semiconductors, and amorphous silicon (Chittick et al., 1969; Okaniwa et al., 1983) in the following decades meant huge strides toward flexibility and processability, and thus these materials became the base for electronic devices in applications that require bending, rolling, folding, and stretching, among other properties that cannot be fulfilled by conventional electronics (Cheng and Wagner, 2009) (Figure 1).
UR - http://hdl.handle.net/10754/667571
UR - https://www.frontiersin.org/article/10.3389/felec.2020.594003/full
U2 - 10.3389/felec.2020.594003
DO - 10.3389/felec.2020.594003
M3 - Article
SN - 2673-5857
VL - 1
JO - Frontiers in Electronics
JF - Frontiers in Electronics
ER -