TY - JOUR
T1 - Room-temperature nanosoldering of a very long metal nanowire network by conducting-polymer-assisted joining for a flexible touch-panel application
AU - Lee, Jinhwan
AU - Lee, Phillip
AU - Lee, Ha Beom
AU - Hong, Sukjoon
AU - Lee, Inhwa
AU - Yeo, Junyeob
AU - Lee, Seung Seob
AU - Kim, Taek Soo
AU - Lee, Dongjin
AU - Ko, Seung Hwan
PY - 2013/9/14
Y1 - 2013/9/14
N2 - As an alternative to the brittle and expensive indium tin oxide (ITO) transparent conductor, a very simple, room-temperature nanosoldering method of Ag nanowire percolation network is developed with conducting polymer to demonstrate highly flexible and even stretchable transparent conductors. The drying conducting polymer on Ag nanowire percolation network is used as a nanosoldering material inducing strong capillary-force-assisted stiction of the nanowires to other nanowires or to the substrate to enhance the electrical conductivity, mechanical stability, and adhesion to the substrate of the nanowire percolation network without the conventional high-temperature annealing step. Highly bendable Ag nanowire/conducting polymer hybrid films with low sheet resistance and high transmittance are demonstrated on a plastic substrate. The fabricated flexible transparent electrode maintains its conductivity over 20 000 cyclic bends and 5 to 10% stretching. Finally, a large area (A4-size) transparent conductor and a flexible touch panel on a non-flat surface are fabricated to demonstrate the possibility of cost-effective mass production as well as the applicability to the unconventional arbitrary soft surfaces. These results suggest that this is an important step toward producing intelligent and multifunctional soft electric devices as friendly human/electronics interface, and it may ultimately contribute to the applications in wearable computers. A very simple, room-temperature nanosoldering of a Ag nanowire percolation network by conducting-polymer-assisted nanowire joining is developed to demonstrate highly flexible, and even stretchable, transparent conductors. Furthermore, a large area (A4-size) transparent conductor and a flexible touch panel on a non-flat surface are fabricated to demonstrate the possibility of cost-effective mass production and the applicability to the unconventional arbitrary soft, non-flat surfaces.
AB - As an alternative to the brittle and expensive indium tin oxide (ITO) transparent conductor, a very simple, room-temperature nanosoldering method of Ag nanowire percolation network is developed with conducting polymer to demonstrate highly flexible and even stretchable transparent conductors. The drying conducting polymer on Ag nanowire percolation network is used as a nanosoldering material inducing strong capillary-force-assisted stiction of the nanowires to other nanowires or to the substrate to enhance the electrical conductivity, mechanical stability, and adhesion to the substrate of the nanowire percolation network without the conventional high-temperature annealing step. Highly bendable Ag nanowire/conducting polymer hybrid films with low sheet resistance and high transmittance are demonstrated on a plastic substrate. The fabricated flexible transparent electrode maintains its conductivity over 20 000 cyclic bends and 5 to 10% stretching. Finally, a large area (A4-size) transparent conductor and a flexible touch panel on a non-flat surface are fabricated to demonstrate the possibility of cost-effective mass production as well as the applicability to the unconventional arbitrary soft surfaces. These results suggest that this is an important step toward producing intelligent and multifunctional soft electric devices as friendly human/electronics interface, and it may ultimately contribute to the applications in wearable computers. A very simple, room-temperature nanosoldering of a Ag nanowire percolation network by conducting-polymer-assisted nanowire joining is developed to demonstrate highly flexible, and even stretchable, transparent conductors. Furthermore, a large area (A4-size) transparent conductor and a flexible touch panel on a non-flat surface are fabricated to demonstrate the possibility of cost-effective mass production and the applicability to the unconventional arbitrary soft, non-flat surfaces.
KW - nanosoldering
KW - percolation networks
KW - polymer-assisted joining
KW - silver nanowires
KW - touch panels
KW - transparent conductors
UR - http://www.scopus.com/inward/record.url?scp=84883817963&partnerID=8YFLogxK
U2 - 10.1002/adfm.201203802
DO - 10.1002/adfm.201203802
M3 - Article
AN - SCOPUS:84883817963
SN - 1616-301X
VL - 23
SP - 4171
EP - 4176
JO - Advanced Functional Materials
JF - Advanced Functional Materials
IS - 34
ER -